The Engines of Our Ingenuity: An Engineer Looks at Technology and Culture

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Author: John H. Lienhard IV

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The Engines of Our Ingenuity

OXPORD UNIVERSITY PRESS

OXFORD UNIVERSITY PRESS Oxford New York Auckland Bangkok Buenos Aires Cape Town Chennai Dar es Salaam Delhi Hong Kong Istanbul Karachi Kolkata Kuala Lumpur Madrid Melbourne Mexico City Nairobi Sao Paulo Shanghai Taipei Tokyo Toronto

Mumbai

Copyright © 2000 by John H. Lienhard First published by Oxford University Press, Inc., 2000 First issued as an Oxford University Press paperback, 2003 198 Madison Avenue, New York, New York 10016 www.oup.com Oxford is a registered trademark of Oxford University Press All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, without the prior permission of Oxford University Press. Library of Congress Cataloging-in-Publication Data Lienhard, John H., 1930The Engines of Our Ingenuity: an engineer looks at technology and culture / by John H. Lienhard. p. cm. Includes bibliographical references. ISBN 0-19-513583-0 (CLOTH) ISBN 0-19-516731-7 (PBK) 1.Technology—Social aspects. 2. Creative ability in technology. I. Title. T14-5.L52 2000 303.48'3—dc2i 99-37614 Four lines of "The Man with the Blue Guitar" are from Collected Works by Wallace Stevens. Copyright 1936 by Wallace Stevens and renewed 1964 by Holly Stevens. Reprinted by permission of Alfred A. Knopf, a Division of Random House, Inc.

Book design by Adam B. Bohannon 9 8 7 6 5 4 3 2 1 Printed in the United States of America on acid-free paper

Contents Preface vii 1 Mirrored by Our Machines, 3 2 God, the Master Craftsman, 20 3 Looking Inside the Inventive Mind, 35 4 The Common Place, 55 5 Science Marries into the Family, 70 6 Industrial Revolution, 86 7 Inventing America, 96 8 Taking Flight, 115 9 Attitudes and Technological Change, 126 10 War and Other Ways to Kill People, 139 11 Major Landmarks, 153 12

Systems, Design, and Production, 167

13 Heroic Materialism, 179 14 Who Got There First, 193 15 Ever-Present Dangers, 209 16 Technology and Literature, 219 17 Being There, 229 Correlation of the Text with the Radio Program, 241 Notes, 243 Index, 255


Preface It would seem only reasonable that, to tell the story of technology, one must first learn something about that great sprawling enterprise. In my case, I worked for a half-century as an engineer and that was after spending a childhood building model airplanes and homemade replicas of all the dazzling new twentieth-century machines. Then I read a whole library-full of books about technology. All that has left me with a keen understanding of the blind beggars who came upon an elephant. As those fabled beggars stumbled into various parts of the elephant—its side, its ear, its trunk—one beggar thought the animal was a wall, another a leaf, another a serpent. We too might as well be blind when we meet the elephant of technology, for it is far too large for any of us to see whole. What you will find here is a progression of seventeen glimpses of the creature, seventeen chapters describing what I have known of the elephant's foot, its tail, its tusk. Of course there is so much more of the elephant than anyone could ever hope to contain in a book. Every overview of technology ever compiled has necessarily been arbitrary— fine accounts of the elephant's eye or of its leg. So I make no apologies for the particular roll of the dice that made this book. It is based loosely on the first year's broadcasts of my daily Public Radio series, The Engines of Our Ingenuity. Those programs have dealt with human ingenuity and creativity seen largely through the window of history, and they set the tone of the series ever since. I have organized those early scripts into chapters, throwing some programs away and adding a few from later in the series to flesh out ideas. Then I rewrote each set to form it into a single essay on one facet of our technological enterprise. The result is not meant to be a work of history. Insofar as I deal with history, the book is largely derivative. It is, instead, commentary and autobiography. (Though autobiography always lurks in the shadows, I

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keep it muted until the last chapter.) I try to convey the texture of the elephant's tail in one chapter and of its tusk in another. And I try to tell what it means, at last, to bond with the beast. I stress in Chapter Fourteen that no good work—no invention and no book—is one person's doing. This book is filled with the good will of hundreds of people whose contributions flow through it: KUHF-FM radio station personnel, colleagues, librarians, university administrators who have supported the work, listeners from around the world (Armed Forces Radio and the BBC have carried Engines programs internationally), friends and family. I identify contributors to the radio program in The Engines of Our Ingenuity web site where complete transcripts (and more) may be found. While these people have also contributed in spirit to the book, I restrict the credits below to those people who have helped bring this book into being. The idea of making the scripts into a book was first suggested by Bill Begell, then president of Hemisphere Publishing Corp. The project was begun in 1989, but it eventually perished when Hemisphere passed to companies whose interest was in technical textbooks and handbooks. Peter Gordon, then president of Textware Corp., took the project over in 1996. His energy, enthusiasm, and critical edge breathed new life into it. When Peter closed his company and took a senior editorship with Oxford University Press, he took the project with him. It was on the advice of Kirk Jensen at Oxford University Press that I changed the format from a set of stand-alone, 5oo-word scripts to a loosely connected set of seventeen essays. Such a format better suits a reading audience just as the short scripts suit listeners. I am grateful to him and to the many people at Oxford who have finally made this work into a book. Susan Day managed the editorial task and provided countless improvements in the text. I am also deeply indebted to many friends who have critically read chapters of the manuscript. First among these are two people: Carol Lienhard has not only turned her discerning eye upon every word in the book, but on all the radio scripts that preceded it; Dr. Jeff Fadell, linguist and librarian at the University of Houston, has edited both the manuscript and the entire set of Engines scripts. These two very different views have played formative roles in shaping what you will find when you turn this page. John H. Lienhard September, 1999

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1

Mirrored by Our Machines

mirror is a strange device. Stand in front of one and what comes back is not the you that you know. Rather, it is you, turned about and shown to you in a crazy literal way. You see the exact reverse of what others see when they look at you. If a photographer hands you a picture (taken in just the right way) of me standing before a mirror, you might have a hard time telling which is the reflection and which is the reality. Mirrors put us off balance by being both literal and subtle at the same time. When I call our technologies mirrors of ourselves I do not do so lightly. An alien looking at Earth for the first time would certainly seek to know us by gazing upon our reflection in our machines. Indeed, that is what anthropologists do when they examine the alien skeletons of our ancient forebears. Before anthropologists identify a particular primate skull as human, they search the area where they found it for evidence of toolmaking. The very word technology helps us understand this process. The Greek word TexvT] (or techne) describes art and skill in making things. Tsxvr\ is the work of a sculptor, a stonemason, a composer, or an engineer. The suffix -ology means the study or the lore of something. Technology is the knowledge of making things. Some people have argued that we should not call our species Homo sapiens, "the wise ones," but rather Homo technologies, "they who use Texviq," for that is who we are.

A

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There is more to Texvn+ology than that. We freed our hands by walking on our hind legs before we took up toolmaking, and we made our earliest stone tools some 2.4 million years ago, while our skulls still accommodated a relatively small brain. Our capacity for thought began to grow as we created increasingly sophisticated implements. Technology has driven our brains. Our expanded physical capabilities made technology—extended toolmaking—inevitable. Technology has, in turn, expanded our minds and fed itself. At first, the notion that technology drives our minds may be surprising. Shouldn't it be the other way around? After all, we teach people to be technologists. We train their minds so they can dictate the course of technology. Yet who on this planet would be clever enough to invent, say, a microcomputer? Who did invent the microcomputer? The answer is that nobody did. It invented itself] At each point in its evolution the machine revealed more of its potential. In each stage it exposed one more step that this or that person recognized and leaped to complete. One Christmas my wife and I gave a primitive Vicao home computer to our then-fifteen-year-old son. He vanished into his room for two weeks and emerged about Epiphanytide (appropriately enough), able to program in Basic. Who taught him? The computer did. It expanded his mind and made him more than he was. He came out of his room changed. Like all of us, he was being shaped by his technology. Technology, the lore of making and using implements, is a primary element in our cultural heritage. The tools, implements, and machines around us enfold and instruct us from birth to death. In this sense I am hardly guilty of hyperbole when I say that the computer invented itself. We instinctively build machines that resonate with us. The technologies of writing and printing each altered the way we see the world. Each opened our eyes to the expanded possibilities they presented to us. Each profoundly changed our civilization. The automobile led to things that never crossed the minds of its inventors. It led us, for good or for ill, to invent highway systems and to change the form of cities. The invention of the telephone altered the texture of human interaction. When someone asked Wilbur Wright the purpose of his new flying machine, he answered, "Sport, first of all." The airplane had yet to serve as a mirror that would reveal our deeper dreams and needs. So we begin to understand technology and humankind when we step through the mirror of our machines, when we weigh the chicken-or-

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egg question of whether the mind drives technology or technology drives the mind, and when we look at the way the existential fun of making things is born in the interaction between our own inventiveness and the technology that surrounds and drives our thinking. A good place to start is with one of the most important of all human technologies: farming. Farming was one of the great steps we had to make on the way to fulfilling our destiny as a species of builders and makers. We had to leave hunting and gathering and assume control of the wealth of the land. The key circumstance triggering that great leap forward was a remarkable pair of genetic accidents. Archaeological evidence shows us the two events that set the stage. Before 8000 B.C., the ancestor of wheat closely resembled a wild grass rather than the rich grain-bearing plant whose seeds we eat today. Then a genetic change occurred in which this plant was crossed with another grass. The result was a fertile hybrid called emmer, with edible seeds that blew in the wind and sowed themselves. In 8000 B.C. a hunting-gathering people called the Natufians lived in the region around Jericho and the Dead Sea. By then, the climate had been warming for two thousand years. Once the area had been fairly lush. Now it grew arid. Game moved north and the vegetation changed. The wild grains grew well in a drier climate, and the Natufians began shifting their diet toward grain. They took to harvesting and eating the emmer seeds. But they didn't have to worry about planting emmer because it sowed itself. The second genetic accident occurred sometime before 6000 B.C. It yielded something very close to our modern wheat, with its much plumper grain. But the new grain, even if it was fertile, could not survive on its own. Although wheat is far better food than emmer, its seeds don't go anywhere. They are bound more firmly to the stalk and are unable to ride the wind. Without farmers to collect and sow wheat, it dies. Modern wheat created farming by wedding its survival to that of the farmer, and it left us with a great riddle: How did modern wheat replace those wild grains? We don't know, but we can guess. The Natufians probably reached the point of planting their own emmer to supply the grain they needed. Once they did, the fat wheat had its chance because it was easier to harvest. Its seeds don't blow away when you cut it. Every time the Natufians harvested seed, they got proportionately more of the mutations and lost more of the wild grain.

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It took only a generation or so of planting before the new grain took over. In no time at all, modern wheat dominated the fields. That was both a blessing and a curse. The Natufians unwittingly replaced the old wild wheat with a higher-yield crop. But it was a crop that could survive only by their continued intervention. No more lilies of the field! From now on we would live better, but we would also be forever bound to this new food by the new technology of agriculture.1 And so the technology of farming mirrors the farmer. Humans created farming, and farming made humans into something far different from what they had been. Top: Modern white Gaines wheat. The process was no different than my son's interaction Middle: Emmer. with that primitive computer. Bottom: A wild wheatlike grass, We can see just how deeply this process of mirroring triticum monococcum. runs through all our technologies (and the sciences that, as we shall see, have been built upon those technologies) if we look at units of measurement. When Protagoras said that "Man is the measure of all things," almost twenty-five hundred years ago, he was closer to literal truth than we might at first think. The gauges and meters we use to measure things usually begin by copying our own senses. All our weights and measures, in some way or another, reflect what we see and feel. A pound or a kilogram, for example, is roughly the mass of any fairly dense material, like a rock or a piece of metal, that we can hold comfortably in our hand. The inch, foot, yard, and meter all correspond roughly with various body parts. The mile and kilometer also have a meaning that is made clear in parts of rural America where people talk about the distance of a "see." Ask someone in eastern Kentucky how far it is into town and he might say, "Oh, 'bout two sees." He means you should look down the road as far as you can see. Where your vision runs out, you spot, say, an oak tree. You walk to it and look again. There, in the distance, is the town, just two sees away. How far is a see? Of course it varies. But even in flat terrain our ability to make things out usually ends after about a kilometer or, at best, a mile. We divide thermometers into degrees Fahrenheit or Celsius, and these are roughly the smallest increments of temperature we can feel. We usually know if we have a one-degree fever. We can sense about one volt with our tongue; our ears are sensitive to about one pound per square inch of pressure change; and so on.

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The units of a kilowatt or a horsepower represent roughly the power most of us can produce in a short sprint—like running upstairs. By the way, the unit of a horsepower is less than the short-term work of a real horse, but considerably more than a horse can sustain all day long. Not only is the kilowatt or horsepower close to the maximum power you or I can produce in a short burst; it is also the most power we can tangle with without being hurt. They represent about as much energy as the sun pours on us if we lie on the beach at midday, or the rate at which we consume energy when we take a hot shower.2 Since we are the basis for most measuring devices, science reflects the world in human terms. But that is not really so bad. Most scientists know perfectly well that science has not yet reached ultimate truth of any sort. The work of science nevertheless yields constructs that make our experiences predictable. Today's science-based engineering obviously has to mirror human needs and human nature. And so does science itself. Still, the immediate reflection of our own bodies in the physical measures that we use every day leaves us struggling at each turn to see more objectively—to shake off human limitations. The magnitude of that problem emerges when we pose a deceptively simple question, "Should we regard a certain object as big or small?" To answer, we instinctively refer to the size of our own body. We understand size on the scale we experience it, and we can be surprised by how differently an object will behave when it is much larger or smaller than our bodies. To see what I mean, you might try this experiment: First find a very large metal sphere and a very small one—say, the big steel ball used in the shot put and a BB. Now drop each from a height of a few feet into a swimming pool. You will see that the shot splash is not at all like a scaled-up BB splash. The large shot sends out a sheet of water that breaks into a fine spray of drops. There are only a few drops in the BB splash. In fact, that's how we know whether the naval battle in a movie is a scale model or footage from a real battle. The splashes look wrong in the scale model. I once knew a badly crippled construction worker. He had been working on the ledge of a building that was being demolished when he saw a two-ton scoop swinging toward him—very gently, very slowly. He put out his hands to stop it as he might have stopped a child on a swing, and when it reached him, it very gently crushed him. His experience with playground swings had grievously misled him about the behavior of two-ton scoops.

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Engineers think a lot about making scale models of big prototypes. We would not get very far if we had to make full-size wind tunnel tests of a Boeing 747. The trick is to set the conditions in a small model so that its behavior is similar to the large prototype. We really could use a BB experiment to learn what a large shot does when it hits water if we changed two things. The BB would have to move much faster than the shot, and we would have to put just the right amount of detergent in the water to cut its surface tension. The forces that dominate this process (inertia, gravity, and surface tension) all vary in different ways with size. The theory of modeling tells how to stretch the dimensions of the relevant variables into universal values. When we do that, surprising things happen. Suppose, for example, that we want to scale up instead of scaling down. Suppose we want to study the movement of microorganisms in our body fluids using laboratory experiments in the visible world. Modeling theory tells us we can do this if we stretch time and magnify liquid resistance. We can replicate the motions of blood cells or spermatozoa by moving large models of these organisms very slowly through cold honey. Sir George Cayley, born in 1773 in Yorkshire, came to a remarkable insight about scaling physical phenomena when he was a young man trying to solve the age-old riddle of human flight. Cayley made a number of key discoveries, but none was more surprising than his realization that trout have the ideal, minimum-resistance, body shape for an airplane.3 Why a trout and not a bird? It is because the flow of water around a fish and the flow of air around a bird of the same size are very different. A century later we had the rules of dynamic similitude. They show that when we scale the interactions of viscous and inertial forces, a small fish in water moves far more like a large machine in the air, than a small bird in the air does. That's why the design of subsonic airplanes eventually settled on a shape far more like fish than birds. Our machines still mirror our experience, but now that experience is tempered by scientific theory. So the problem of modeling is one part of a general problem we face whenever we design things. We have to find ways to see what is not

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obvious to our eyes. We have to find ways to predict complicated behavior before it becomes part of our experience. Our modern systems of weights and measures evolved as scientific instruments gave increasing precision and definition to measurement. However, technology reached high levels of sophistication long before we had any such apparatus. My grandmother used to tell me that if I burned my finger, I should dip it in a cup of tea. She knew that before doctors knew anything about the healing power of the tannic acid in tea. My grandmother's finely honed intelligence was in no way lessened by the fact that she'd never studied organic chemistry. Take the ancient technology of Japanese sword making, which reached an astonishing perfection twelve hundred years ago. A samurai sword is a wonderfully delicate and complex piece of engineering. The steel of the blade is heated, folded, and beaten, over and over, until the blade is formed by 32,768 layers, forge-welded to one another. Each layer is o.ooooi inch thick. All that work was done to very accurate standards of heat treatment. The result was an obsidian-hard blade with willowlike flexibility. The blades represented a perfection of production standards that has yet to be matched by modern quality control. The Japanese craftsmen who made them knew nothing about temperature measurement or the carbon content of steel. How do you suppose they got it right, again and again? The answer is one we are well advised to remember. Sword making was swathed in ceremony and ritual. It was consistent because the ceremony was precise and unvaried. Heat-treating temperatures were controlled by holding the blade to the color of the morning sun. The exact hue was transmitted from master to apprentice down through the centuries. Sword making was a part of Japanese art, and it was subsumed into Japanese culture.4 That form of quality control was not unique to the Japanese. It was true of eighteenth-century violin making and it is still true in other older technologies that survive today. Ritual can do much of what we do with weights and measures. Our intelligence, after all, runs deeper than our ability to read gauges. Great technologies arise out of a full range of experience. They come from creativity triggered by more than tables of technical data. Good technology is not independent of culture. The best

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doctor knows organic chemistry as well as his grandmother's folklore. The best metallurgist knows about iron-carbon phase diagrams but can see those diagrams in the light of a bright yellow-orange blade emerging from the forge. Years ago I worked for a seasoned design engineer. One day he looked at a piece of equipment and said, "Look at that heavy gear running on that skinny shaft. Some designer didn't use his eyes." The best engineers know math, physics, and thermodynamics, but they also know the world they live in. The best engineers bring a visceral and human dimension to the exacting math-driven, science-based business of shaping the world around us. The machines they produce therefore mirror themselves. The easiest place to see the mirror of technology is in the language we use to talk about our technologies. The words science, technology, and engineering take a terrible beating. Who makes a spaceship fly—a scientist, a technologist, or an engineer? Who should shoulder the blame if it fails? These questions are easier to answer if we really understand what the words mean. The word science comes from the Latin word scientia, which means "knowledge." We apply the word science to ordered or systematic knowledge. A scientist identifies what is known about things and puts that knowledge into some kind of order. We have noted that the word technology combines the Greek word TSXv1fl (combined art and skill) with the ending -ology (the lore or the science of something.) In its role as the science of making things, technology stands apart from the actual act of glassblowing or machining. It is the ordered knowledge of these things. It is also our instinct for sharing our knowledge of technique. Our language would be a lot clearer if we could reclaim the old Greek word is\vr\ and restrict its use to describing the actual act of making things. The last of the three words, engineering, comes from the Latin word ingenium. That means "mental power." English is full of words related to ingenium: ingenuity, which means "inventiveness," and engine, which can refer to any machine of our devising—any engine of our ingenuity. So an engineer, first and foremost, devises machines. For about three hundred years science and TexvT) have joined forces. We talk more about that in chapter 5. Today's engineers are technologists who are well schooled in science and can make effective use of it when they try to create the engines of their ingenuity.

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Which of the three, scientist, technologist, or engineer, deserves the credit for the success, or blame for the failure, of a spaceship? The answer, of course, is that the question is no good. The three functions of Tex^TH, science, and invention work together to make a spaceship. Engineers combine these functions. One engineer might behave more like a craftsman—a user of TexVTl — while another might behave more like a scientist, refining background information for designers. But people earn the title engineer when the goal of their labors is the actual creative design process—when they combine a knowledge of Tsxvf] with science to achieve invention. Look further at words, at the way we name our machines. A machine normally receives its permanent name only after it has achieved a certain level of maturity— Top: Langley's Aerodrome. Center: Henson's Aerostat. after it has settled itself into our lives. Take Bottom: Moy's Aerial Steamer. the airplane. A hundred years ago, we had dozens of terms to describe it: aerial velocipede, aerial screw machine, aero-motive engine, bird machine, and flying machine. Most of these names vanished ten years after the Wright brothers flew. Now we have settled on just two terms, airplane and aircraft. No one I knew had a refrigerator when I was little. We had an icebox with a rack on top where we put a new fifty-pound block of ice every few days. I still forget, and annoy my sons, by calling our refrigerator an icebox. During the 19305 we tried all kinds of terms for the new machine—Frigidaire, electric icebox, and of course refrigerator. The words engine and machine show up repeatedly when devices are first named. They are from Latin and Greek roots and broadly refer to devices that carry out functions. The steam engine was first called zfire engine, and it still keeps the engine part of its name. We still say sewing machine, but no one calls a telescope an optical engine anymore (as they did in the seventeenth century). I especially like the name Babbage gave his first programmable computer in the early eighteenth century. He

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called it an analytical engine. Software packages for checking programs were called parsing engines long before another engine word attached itself to computers: the now-common term search engine. Foreign names stick to new gadgets for a while, but they tend to fade. Airplane designers have moved away from the French words empennage, fuselage, and nacelle in favor of the English equivalents: tail, body, and pod. The German name zeppelin was given to one form of what the French call a dirigible. Nowadays we are increasingly inclined to use the English word airship. We call a writing desk an escritoire only when we want to run up its price. The first names we give new technologies often tie them to older ones. An early name for the first airships was aerial locomotive; railway passengers still ride in coaches', and airplane passengers pay coach fares. Finally, a game we all might play: Over the next decade, track the changing computer-related names. Watch as we run through words such as screen, CRT, and monitor, or Internet and Web. Watch us select among names like microcomputer, PC, workstation, or simply the machine. Watch as those systems become metaphors for who we are. When we finally settle on names, what we shall really be doing is taking the machine fully into our lives. Thus far, I have described the mirror of our technology in fairly objective terms, but technology lies too close to the human heart to be dealt with in such a straightforward way. The mirror reflects aspects of our nature that are not immediately obvious to ourselves. I can clarify my meaning here by asking yet another question: What is the oldest human technology? Farming developed late in human history. Before farming, settled herdsmen and gatherers made clothing, knives, tents, and spears, but so did nomads before them. Go back further: Archaeologists show us that pictures and music were among the Stone Age technologies. Magnificent cave paintings have survived since the beginning of the Upper Paleolithic period—at least twenty-five thousand years ago. Along with them we found evidence of rattles, drums, pipes, and shell trumpets. Even the Bible, the chronology of the Hebrew tribes, identifies the making of musical instruments as one of three technologies that arose in the seventh and eighth generations after Adam. Music is clearly as old as any technology we can date. Couple that with the sure knowledge that whales were composing complex songs long before we walked this earth—that the animal urge to make music

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precedes technology—and I offer music making as my candidate for the oldest technology. The societies with the least technology still make sophisticated music. Song, dance, musical instruments, and poetry are central to ancient Australian Aborigine culture. Music is the most accessible art and, at the same time, the most elusive. In almost any age or any society, music making is every bit as complex as other technologies. But our own experience tells us as much as archaeology does. Experience tells us that music is primal. It is not just a simple pleasure. Jessica says to Lorenzo in Shakespeare's Merchant of Venice: "I am never merry when I hear sweet music." Lorenzo replies, The reason is your spirits are attentive,... The man that hath no music in himself,... Is fit for treasons,...

And we know what he means! If we cannot respond to art, to music, then something is missing and we are fit for treasons. Music helps us understand the human lot. Music is as functional as any worthwhile technology. Its function is to put reality in terms that make sense. That means dramatizing what we see—transmuting it into something more than is obvious. Poet Wallace Stevens wrote: They said, "You have a blue guitar, You do not play things as they are." The man replied "Things as they are Are changed upon the blue guitar."5

The blue guitar—music, or any art—does change reality. It turns the human dilemma around until we see it in perspective. Sometimes it takes us through grief and pain to do that, disturbing us at the same time it comforts us. But it serves fundamental human need. So it is no coincidence that the technologies for creating art, and music in particular, preceded all else. Those subjective factors are always at work, shaping technologies to serve us best—shaping them to serve more elemental needs than are evident. The reason technology is impossible to predict is that our pre-

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dictions are inevitably shaped by those factors that are fairly evident. Imagine for a moment that the year is 1800 and we are called upon to predict the nature of American culture once it has moved west of the Mississippi. I doubt any of us could have come close. What actually happened was that the American West developed highly characteristic technologies for daily life. We all know the texture today: log cabins, windmills, card games, heavy horse-drawn wagons, whiskey, large saddles, and (I might ominously add) death by hanging. Historian Lynn White pointed out a startling feature of all these technologies: their link to the Middle Ages. Log cabins were a medieval form of housing; the earlier Romans and later Europeans used much different building technologies. The Romans and later Europeans drank beer and wine, but whiskey was the medieval drink of choice. Romans and eighteenth-century gamesmen used dice, but you would find only cards in medieval or western saloons. That sort of comparison can be made right down the line. The Romans executed people by crucifixion and the later Europeans used beheading and shooting, but strangulation—hanging—was the standard medieval punishment. The strange parallel grows more puzzling when we learn that the middle-class settlers of New England tried to re-create what they had left behind, instead of looking for the most efficient technologies. They tried to go straightaway to the beam-and-plank method of house construction they had used in England, even when log houses made better sense. But the settlers of the West were generally from the European lower classes. They were peasants, workmen, and people who had lived away from the sophisticated centers of Europe. Their lives had generally been closer to the technologies of the Middle Ages. These people found their way more quickly to the sort of rough-hewn ways that worked so well in both the medieval world and the undeveloped West. They also held little nostalgia for the current styles in Europe.6 White's suggestion bothered many other historians. He did not explain the similarities, and people do not like what cannot be explained. Yet, in a way, it seems fairly evident. The technologies of the eleventh through the fifteenth centuries were wonderfully direct, practical, and inventive, and so too were the immigrants to the American West. Medieval life and western life were open to variety and change. What the Old West really did was to mirror medieval life accurately, because it was populated by free and inventive people who knew how to

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adapt to new circumstances. They allowed light to pass through that mirror, and the result was one that was totally unpredictable. Once those technologies were in place they had a staying power that allowed them to endure long after we might have expected them to have fallen by the wayside. The western farm windmill is an icon that will not easily yield to small electrical pumps. The playing cards remain. Cowboy clothing has been stylized and stays with us long after we've forgotten its distinct purposes. Case in point: the old railway train caboose. The caboose was a kind of moving rear observation tower—a way of seeing over and beyond a railway train. Electronic safety systems have made them obsolete, but cabooses are so woven into the fabric of railroading that in 1980 railroad companies were caught up in a bitter debate as to whether they should be abandoned. So goes the story of lighthouses as well. Lighthouses call up the romance of the sea just as powerfully as cabooses complete the image of railroading in our mind's eye. Lighthouses are used to mark all kinds of dangers to shipping at night—sea crossings, rocks, major landfalls. Height is important: a y-foot-tall light can be seen four and a half miles away, a i2o-foot-tall light is visible for more than twelve miles, and so forth.

That's why the Pharos at Alexandria was so large. One of the seven wonders of the ancient world, it held a huge bonfire four hundred feet in the air. And, like it, lighthouses through the centuries have usually been tall masonry towers mounted on the shore, or maybe on shoreline cliffs, burning wood, olive oil, or, later, coal or candles. It was a pretty static technology. Rotating beams were not invented until 1611. It was 1763 before reflectors were finally placed behind lamps to boost their power. The first lens was introduced less than two hundred years ago. Lighthouse construction started moving again in 1698 when the English had to warn ships away from the Eddystone rocks, fourteen miles southwest of Plymouth. You might well know about the lighthouse that was eventually put there through this old folk song:

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Oh, me father was the keeper of the Eddystone light, And he slept with a mermaid one fine night. And from this union there came three, A porpoise and a porgy—and the other was me. Building the Eddystone light was a terrible job that greatly advanced the whole technology. It had to be erected right at sea level, where it was hammered by waves. The first one, made of wood, lasted five years. The next, made of wood and iron, burned down after forty-seven years. The great English engineer John Smeaton designed and built the third Eddystone lighthouse in 1759. He used a new kind of interlocking stone construction that was not replaced by the present Eddystone light until 1881. But now radar, sonar, and electronic buoys are putting an end to the lighthouse. We will have to live in a world without cabooses on trains, and without those beautiful storm-beaten minarets to call the weary sailor home. The siren attraction of the lighthouse, like other technology past (and, I suppose, like much technology yet to come), is that good technology is contrived to fulfill human need. That is why it satisfies more than function—why it expresses what is inside us. All good technology acquires symbolic as well as functional power. That is the reason we are so loath to say good-bye to it. Sometimes the metaphor races ahead of function. That happens today, but it is usually too hard to sort out while it's happening. Go instead back to the world of the 19305. The watchword in those days was modern. If I knew one thing as a child, it was that I lived in the modern world. It was a world where the vertical lines of art deco were giving way to horizontal streamlined forms. Everything in the 19305, '405, and '505 was streamlined. The Douglas DC~3 had brought streamlining to passenger airplanes. The Chrysler Airflow and the Lincoln Zephyr brought it to the automobile. Even my first bike was streamlined. Earlier in the twentieth century, the great German experts in fluid flow had shown us how to streamline bodies to reduce wind resistance. Streamlining certainly served this function when things moved fast. But my bicycle hardly qualified. Nor did the streamlined Microchef kitchen stove that came out in 1930. Bathrooms were streamlined. Tractors were streamlined. Streamlining was a metaphor for the brave new world we all lived in.

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A confusion of design schools competed with each other in the early 19305. The German Bauhaus school had been scattered by the Nazis. Art deco was dying. Neither the classic colonials nor Le Corbusier and the other architects associated with the International Style could gain ascendancy. Then streamlining came out of this gaggle, propelled by American industry and making its simple appeal to the child in all of us. It certainly appealed to the child I was then. Of course, streamlining was in part a sales gimmick—something to distract us from the tawdry realities of the Depression. It told us to buy things. It told us we could all go fast. It was hardly one of the great humanist schools of design. The Nazis and Bolsheviks used streamlining as a propaganda tool. American industry used it to make us into consumers. It hinted at the daemon of technocracy. It lasted until the 19505, when its dying excesses—enormous tail fins and chrome bumpers—made the automobile seem ridiculous by most esthetic standards.7 But I loved airplanes as a child, and the functional curved aeroform shape touched something in me. The way the gentle camber of an airfoil gave the invisible wind a handle by which to pluck a fifty-ton airplane into the sky—that was truly magical. "When I was a child," Saint Paul said, "I thought as a child." Streamlining may well have been a childish symbol of our modern world, which we have now put away with other childish things. But I still look back with suppressed joy at that vision of motion, speed, and buoyancy—at the DC~3, the 1949 Studebaker, even big tail fins. That child is still in me. Perhaps the mirror becomes most treacherous when machines converge with human perception. Professor Kenneth Torrance of Cornell University gave a talk back in 1988 that inadvertently dramatized this theme. He began by using computer graphics to create simple scenes— a crib in a room, ajar on a table. To illuminate his scenes, he let a computer chew through the complicated equations he had written for the reflection and diffusion of light until the image was lit the same way a lamp or the sun would light it. By then we had seen the first computer-generated images in the movies, but his were much better. Colors appeared just the way they should. They mixed perfectly in the shadows. These pictures had the beauty and accuracy of a Dutch master's work. When Torrance had finished, I was no longer sure whether I was looking at a picture or at the

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thing itself. These were not just artist's creations. Torrance had written the rules of nature and then let the computer obey those rules. In a sense, he had told the computer how to re-create the actual being of nature. Of course, it is not easy to parse reality into the language of computers. Yet when we do, the results are not just stunning, they are disorienting as well. Students of fluid flow struggle to make their computers tell them how fluids move over airfoils, through tubes, past turbine blades. As computers replicate the tortuous swirls of water and air in slowmotion, on a computer screen, we sometimes wonder whether we are seeing reality or the imaginings of a lunatic. By now, the science of computer graphics has moved far ahead and we see stunning machine-generated realities on movie screens or even on our computer monitors. Today's scientist can do many experiments more accurately within the computer than in the laboratory. Yet some computer modeling is terribly deceptive. Its seeming accuracy can miss features that would have been revealed in the laboratory. In either case, as the computer's role expands, we users adopt the language of people dealing with real things. We speak of doing "numerical experiments" when we isolate processes on the machine instead of in the laboratory. We can be disarmingly casual about separating computer and laboratory data. The computer takes a larger and larger role as a partner in human decision making. We no longer can be sure who created the picture we are looking at: an artist, a camera, or a computer. The computer can replicate the sound of a concert grand piano and fool me into thinking that I hear a live person playing a real instrument. As the computer speaks to our senses as well as to our intellects, we start to have trouble finding the line between realities of the machine and realities outside it. Machines mirror our lives. Our lives mirror our machines. We've seen how devices change us. Machines extend our reach and take us where our legs cannot. They amplify our voices. They even give us wings. I talk about machines extending our bodies because that is the way they touch us so powerfully. But replacing our legs with an automobile, or our backs with a forklift, is nothing compared to what computers do. They sit right beside our brains and assume a kind of partnership practically inside our heads. Our relations with machines have always been personal, but with our computers they are terrifyingly so. Just how personal has come home to me in a very real way in recent years.

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Between 1983 and 1988 I wrote everything on my first word processor—papers, talks, letters, and two books, well over a million words of finished copy and several times that in discarded drafts. Imagine, if you can, my intimacy with that machine when, after five years, it became clear that it had grown obsolete. By then it held my thoughts and was giving them back to me. But time had now passed it by. I had no choice but to buy a flashy new computer. Once I did, it worked diligently to further change me. It had ten times the memory of the old machine, two hundred times the storage capacity. It had a colorful new screen. It thought with blinding speed. Now it played chess and Othello with me. It handled several manuscripts at the same time, corrected my spelling, indexed my texts, and tended my files and addresses. It suggested better words for me to use. By the time I was done with the second computer and moved on to a third one with ten or a hundred times more capacity, the second one still held countless surprises I had yet to discover. By now I had realized that each of those new computers knew all the tricks of behavior modification. If I said the wrong thing, the machine stopped talking to me and feigned ignorance. It confided its secrets to me only if I said just the right words to it. During the first month each new computer has kept me on the rack, rewarding me now and then by tossing me a new bone. After a month, the transition begins to complete itself. The new machine is not yet the comfortable old shoe that the one before it had become. But it gets there, and its way of getting there is by changing me. It is in the transition from one machine to another that we come to appreciate their power in our lives. Do you remember your first bike or the first car you drove? Think back for a moment. That bike was like a flying carpet. It changed you, irrevocably. People often ask, "Do these transitions occur for good or ill?" But that's not very helpful, because machine making is an inseparable part of us. We are mirrored by our machines, and the corollary is also inescapable: We mirror our machines. The question is not whether we should let them change us, but whether we are to be lifted up or dragged down in the process. That issue hovers over the rest of what follows as we talk about technology and its place in our lives.

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2 God, the Master Craftsman

dam awoke on the eighth day of creation, measuring his newly gained creative powers. In a harsh, forbidding world, somewhere to the east of Eden, Adam flexed new muscles and smiled. "That garden was nothing," he chuckled. "We're well rid of it. I'll build a garden that'll put it to shame." That eighth day of creation was, in fact, very late in time. Adam had hunted and gathered in the garden for four million years. Then, just the other day—only about thirty thousand years ago—he came into the dense, self-reinforcing, technical knowledge that has, ever since, driven him further and further from the garden. We are a willful, apple-driven, and mind-obsessed people. That side of our nature is not one that we can dodge for very long. Perhaps the greatest accomplishment of the eleventh-century Christian church was that it forged a tentative peace with human restlessness. All the great monotheistic religions of the world have honored God as Maker of the world, but the medieval Christian church went much further: It asserted that God had manifested himself in human form as a carpenter—a technologist, a creator scaled to human proportions. It seemed clear that if we are cast in God's image, then God must rightly be honored as the Master Craftsman. The peace forged between the medieval Church and Adam's apple was wonderfully expressed by an anonymous fourteenth-century Anglo-Saxon monk who sang:

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Adam lay ibounden, bounden in a bond. Four thousand winter, thought he not to long.

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And all was for an appil, and appil that he tok, As clerkes finden, written in their book. Ne had the appil take ben, Ne hadde never our lady, a ben hevene quene. Blessed be the time that appil take was Therefore we moun singen, Deo Gracias! In the mind of that monk, taking the apple of technological knowledge was the first step in spinning out the whole tapestry of the biblical drama that had left him at last with the comfort of his Virgin Mary. So he sang "Deo Gracias," picked up his compass and square, and went to work. No wonder medieval Christianity was such a friend to the work of making things. The great emergence of Western technology can be traced from the medieval Church straight through to the Industrial Revolution. That central fact is easy to forget in light of today's technology, interwoven as it is with a science dedicated to detachment and objectivity. The ideal of objective detachment has evolved only over the last three hundred years, and it misleads us. It causes us to see technology as unrelated to driving forces deep within the human heart. But such detachment is not only very young; it is also something modern engineering designers have begun to question. Designers today are consciously trying to tap into subjective thinking in the creative process. They are increasingly aware that invention is driven by imperatives from deep within us. Historians have begun to see that the technological empire grew out of spiritual seeds sown in medieval Europe. Late-twentieth-century thinking portrays objective science and technology as being, at best, neutral on religious matters. At worst, technology and religion have been portrayed as adversaries. That antagonism grew up as the new experimental sciences began to conflict with literal readings of the Bible. But the quintessential twentieth-century scientist, Albert Einstein, simply gazed at a God whom he acknowledged in only the most abstract terms, and said of his God, "Subtle is the Lord." Modern physics has proven to be subtler than modern theology, and both have come very far from the black-and-white stances of the late Victorian period.They have long since ceased to draw battle lines. We live in a world where technological detachment is inadequate to solve the prob-

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lems we face, where the extremes of mathematical rigor begin to strike mathematicians as sterile, and where scientists acknowledge that their most basic principles are themselves tenets of a specialized faith. If technology and the pursuits of the mind are subjective, they remain willful. But in the medieval view, that willfulness could be harnessed to the greater glory of God. Historian Kenneth Clark paraphrases a moving contemporary description of the construction of Chartres Cathedral, written in 1144. According to this twelfth-century observer: When the towers seemed to be rising as if by magic, the faithful harnessed themselves to the carts which were bringing stone, and dragged them from the quarry to the cathedral. The enthusiasm spread throughout France. Men and women came from far away carrying heavy burdens of provisions for the workmen—wine, oil, corn. Among them were lords and ladies, pulling carts with the rest. There was perfect discipline and a most profound silence. All hearts were united and each man forgave his enemies.1 But before the construction of cathedrals and all the other miracles of medieval invention went into high gear, another Anglo-Saxon monk gave us a powerful lesson in what it meant for him to be cast in the image of the Master Craftsman. The noted twelfth-century English historian William of Malmesbury recorded this event, which took place just after the year A.D. 1000. He says about the monk Eilmer of Wiltshire Abbey: Eilmer...was a man learned for those times,... and in his early youth had hazarded a deed of remarkable boldness. He had by some means, I scarcely know what, fastened wings to his hands and feet so that, mistaking fable for truth, he might fly like Daedalus, and, collecting the breeze on the summit of a tower, he flew for more than the distance of a furlong. But, agitated by the violence of the wind and the swirling of air, as well as by awareness of his rashness, he fell, broke his legs, and was lame ever after. He himself used to say that the cause of his failure was forgetting to put a tail on the back part.2 In other words, this rash monk actually achieved a modestly successful glider flight over a distance of more than two football fields. The

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story gains credence when Eilmer tells us, from across the space of a millennium, that the reason he crashed was that he had failed to equip his glider with the tail it would have needed to give it lateral stability. We have been raised with the idea that flight was finally achieved only in the lifetime of people who are still living. Yet not only the dream of flight but the. fact of it as well has been with us for thousands of years. Kilmer's flight had its own historical antecedents. Somewhat sketchy accounts make it clear that a successful glider flight was made in the year 875 by a Moorish inventor named Ibn Firnas, who lived in Cordoba, Spain. Firnas also crashed, and he too mentioned his failure to provide a tail. The story of Firnas' attempt had almost surely reached Eilmer. Too bad Eilmer didn't listen to the part about the tail! Both these bold and imaginative prototypes of the glider were developed in religious and intellectual environments that fostered invention. Ibn Firnas lived at the height of the golden age of Islamic art and science, and Eilmer belonged to the Benedictine order with its tradition that God is the Master Craftsman. William of Malmesbury, also a Benedictine, undoubtedly knew monks who, as lads, had actually spoken with the aging Eilmer. William writes in the voice of one who delights in Eilmer's bold attempt to harness God's world by natural means. And yet the Benedictine order was no longer the same as it had been in Eilmer's day. In the year 1000 the Black Friars of the Benedictine order were functioning as a driving force for learning and for technology. But great epochs fade. So the Cistercian monastic order was founded as a reform of the Benedictine order in the year 1098. Saint Bernard took charge of the Cistercians fourteen years later and moved the order in a direction that would complete the transformation of European civilization. The Cistercians were still a branch of the Benedictines, but they were a strict branch that fled worldly commerce to live remote from the habitation of man. Under Saint Bernard they achieved this life by the seemingly contradictory tactic of creating economic independence based on the highest technology of the day. During the preceding few centuries, the water wheel had revolutionized western Europe by providing a cheap and convenient power source. It had replaced the backbreaking labor required to grind grain, full wool, and saw wood that had been the beginning and end of most people's lives. The Cistercians finally showed how far the water wheel could be taken.

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By the middle of the twelfth century their order had reached the cutting edge of hydropower and agricultural technology. A typical Cistercian monastery straddled an artificial stream brought in through a canal. The stream ran through the monastery's shops, living quarters, and refectories, providing power for milling, woodcutting, forging, and olive crushing. It also provided running water for cooking, washing, and bathing, and finally for sewage disposal. These monasteries were, in reality, the best-organized factories the world had ever seen. They were versatile and diversified. Of course, they represented a rather strange way of living remote from the habitation of man, but that is another matter. We are too often led to see this period of history as a Dark Age. The people who gave us the written record of medieval political history were generally remote from the world of making things. The scribes of the kings wrote about armies and slaughter and had little to say about the engineers who were really changing the world. And the engineers of the Cistercian order did more than just develop this new technology. They also spread it throughout Europe during the twelfth and thirteenth centuries. Their 742 monasteries were major agents of the changes that had completely altered European medieval life by the middle of the thirteenth century. By A.D. 1200 another power-generating technology took its place alongside the water wheel. The medieval windmill, with its driving fan facing into the wind, was likely an adaptation of the quite different Arab windmill. Arab windmills had vertical fans mounted inside a tower that admitted the wind through vertical slots in its side. The Arabs had been building such windmills for several centuries when the Crusaders arrived. The powerful European windmill that finally burst upon northern Europe in the last years of the twelfth century typically generated twice the power of a medieval water wheel (five or six horsepower as opposed to two or three). Windmills did not displace water wheels, but they supplemented them in different kinds of environments. At this point, medieval millwrights had two radically different power sources, yet both ground grain. And we are left with what is, by our standards, an intriguing and difficult question: To the medieval mind, what powered those mills? What invisible efficacy was taken from the water or the wind to grind grain? The wind, in particular, still captures our imagination even though we know about air, kinetic energy, and

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force balances. What did people see happening in a mill when they didn't have any such knowledge? A little word game yields a startling insight. The ancient tongues all used the same word for "wind," "breath," and "soul." In Sanskrit that word is atman'y in Latin it is either spiritus or anima; in Hebrew it is ranch] and in Greek it is pneuma. Ranch shows up again as the German word for "smoke," and we see pneuma in air-related words such as pneumatic. The Russian word for "spirit," duh, has many wind-related cognates. Duhovyia intrumenti, for example, means "wind instruments." The connection is that both the wind and the soul were the breath of God. Genesis, for example, begins with God breathing a soul into Adam. Medieval engineers saw nothing less blowing their windmills. The power source was mystical. By the way, some historians are pretty sure that the windmill itself was derived from ancient Buddhist prayer wheels that were spun by sail-like propellers. We can describe the wind in technical terms today, but we haven't let it lose its metaphorical power. In his "Ode to the West Wind," nineteenth-century Romantic poet Percy Bysshe Shelley shouts at the west wind, Be thou, Spirit fierce, My spirit! Be thou me, impetuous one! Drive my dead thoughts over the universe, Like wither'd leaves, to quicken new birth. His wind was not just spiritus; it was a renewing spirit, a cleansing new broom—the same imagery we use when we tell each other, "It's an ill wind that blows no good." For medieval engineers, the most plausible explanation of mechanical power was that it was the breath of God. And, by the middle of the thirteenth century, the expanded use of water and wind power had created a kind of mania for such power. The power at the disposal of the average person had roughly quadrupled, and when people saw what it could do for them, they wanted more—and more. The solution that arose during the mid-thirteenth century should not really be a great surprise. People looked for means of harnessing what is called in Latin perpetua mobile—perpetual motion. When you and I talk about a perpetual-motion machine we usually mean one that produces power without being fed an even greater amount of power in a different form—say, an engine that produces elec-

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trical energy without eating even more energy in the form of coal. Since 1850 we have all agreed on thermodynamic laws that tell us such a machine cannot exist. But think for a moment like a medieval engineer, hungry for yet more power. For years we have harnessed the motions of wind and water. We have watched our water wheels turn and turn and turn. We have watched our windmills turn, stop for a while, then turn some more. Our eyes tell us that perpetual motion obviously is possible, for the breath of God is always there. Then, in A.D. 1150, the Hindu mathematician Bhaskara proposed a machine that would produce continuous power. It was simple enough—a wheel with weights mounted around its rim so they swung radially outward on one side and inward on the other. The wheel was supposed to remain out ofbalance and turn forever. Medieval engineers knew nothing about the conservation of either energy or angular momentum. They had no way of understanding that such a machine was doomed to fail. The overcentered wheel reached the Moslems in 1200 and France by 1235. For the next five hundred years, writer after writer recommended this ingenious, if impossible, little device. Did they A late-seventeenth-century form of Fludd's earlier perpetual-motion machines, shown in Bockever try to make one? They did, of course, and the ler's Theatre of New Machines. The reservoir machines always failed miserably. Yet to minds provides water power for both the mill and the that believed perpetual motion possible, failure Archimedean pump that forever resupplies the reservoir. merely meant they did not yet have the proportions quite right. The machines all failed, yet that did not keep hope from remaining alive and well. It was not until the seventeenth century that scientists finally recognized its impossibility. Not until the eighteenth century were mathematical engineers able to show that the overcentered wheel failed to properly conserve momentum. For centuries afterward, each newly revealed physical phenomenon awakened new hopes. Each newly discovered force of nature drove people to look for ways of exploiting it to produce power without consuming energy. The search for perpetualmotion machines finally led contributors to a better understanding of static electricity, surface tension, magnetism, and hydrostatic forces.3 The search for perpetual motion has thus been a powerful techno-

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logical driver, one that remains alive even today. Some people look for it in the face of the physics that says it is impossible, while others simply look for as yet unthought-of ways to keep producing power—for new means of tapping into the breath of God. The first fruit of the search for perpetual motion was the invention of the long-term repetitive motion of the mechanical clock, which was invented around A.D. 1300—give or take a little. The very person who first promulgated perpetual motion in France was the architect Villard de Honnecourt. After his experiments with the overcentered wheel, Villard carried the theme of perpetual motion forward in a different way. He invented a device that pointed at the sun rising in the east and then kept on pointing toward the sun until it set in the west. That device was the first weight-driven escapement mechanism—the heart of what would soon become the mechanical clock (see Chapter 5). Something like perpetual motion had now been realized in a kind of sustained motion that was entirely feasible. The mechanical clock calls to mind its antithesis, the hourglass. How old do you suppose the hourglass is? Two thousand years? Four thousand years? It was invented about the same time as the first mechanical clocks, so it is only about seven hundred years old. The hourglass had some strong characteristics. On the positive side, it was far simpler and cheaper than the mechanical clock or the earlier water clock; resetting it after it ran down couldn't be easier; and it didn't vanish when you used it, the way a graduated candle did. Its accuracy was not bad once some problems had been solved. You could not just load any old sand into it. You had to find a free-flowing material that was unresponsive to humidity. On the downside, hourglasses were short-term timepieces. The very name suggests it is hard to make one that will run more than an hour. In addition they cannot be calibrated. Sand moves downward in jerks. The edge of the sand is uneven. If you mark five-minute intervals on the glass, the sand will hit those marks differently each time you turn it. An hourglass shows only when an hour is up. Hourglasses found their niche in setting off blocks of time: the time between canonical hours in a monastery, or between watches on board a ship. They ran neither long enough nor accurately enough for marine navigation. They were a poor person's timepiece—a kind of clock for everyman.4 Both the mechanical clock and the hourglass played powerful sym-

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bolic roles during the Renaissance. The complex mechanical clock with its rotary gears became a metaphor for the heavenly spheres or the wheel of fortune. But the hourglass, whose sands run out, became a metaphor for the destiny we all inevitably face, and has remained a universal symbol of death. Two technologies, one simple, one complex, running side by side—the clock making a continuum of time and the hourglass segmenting it, the clock speaking of timelessness and the hourglass showing us finality, the clock evoking things celestial and the hourglass reminding us A modem hourglass. of base earth. Two technologies, yin and yang. Why was the hourglass so late in coming? Maybe it had to wait for its antithesis, the mechanical clock, to be invented. Two hundred and fifty years after their invention, mechanical clocks had become very sophisticated machines that, in retrospect, provide insight into the nature of invention. As machines go, clocks have their own distinctive character. You wind them up and then sit back to watch them carry out their function. A well-designed clock goes on and on, showing the time of day without human intervention and without self-correction. That is exactly why the ideal clock—the clock that we almost but never quite make—became a metaphor for divine perfection. By the middle of the sixteenth century, clocks had not only become passably accurate. They had also become remarkably beautiful, adorned with stunning but seemingly useless trimming. Mechanical figures marched out on the hour and performed short plays. Extra dials displayed the movements of planets. Clocks were crowned with exquisite miniature gold, bronze, and silver statuary. The intricate wheels and gears of these baroque clocks became a metaphor for the solar system, the universe, and the human mind, as well as the perfection of God. The best minds and talents were drawn into the seemingly decorative work of clock making because clocks harnessed the imagination of sixteenth-century Europe. All this was rather strange, because there was little need for precision timekeeping. Later, during the eighteenth century, the clock began to assume its role as a scientific instrument—especially for celestial navigation. But in 1600 the search for accuracy was primarily an aesthetic and intellectual exercise.

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Our thinking is so practical today. You or I might very well look back at the sixteenth century and condemn elegance in clock making as a misuse of resources. But the stimulus of the clock eventually resulted in previously unimagined levels of quality in instrument making. It drove and focused philosophical thinking. In the end, the precision of this seemingly frivolous high technology was a cornerstone for the seventeenth-century scientific revolution, for eighteenth-century rationalism, and, in the long run, for the industrial and political revolutions that ushered in the nineteenth century. Sixteenth- and seventeenth-century clock making was the work of technologists who danced to their own freewheeling imaginations and aesthetics—technologists who were having fun. Technologists like that really change their world. And make no mistake, baroque clock makers set great change in motion. In that sense the mechanical clock marked the end of the medieval era. It was more a creature of the age that followed (more about that in a moment). The defining technology of the high Middle Ages was not the agitated moving clock, but the static Gothic cathedral. It is hard to say too much about Gothic cathedrals. They combine immensity with a delicacy of balance and detail that must be seen to be believed. The spire of Strasbourg Cathedral, for example, is almost as high as the Washington Monument. Gothic architecture appeared suddenly in the twelfth century and kept evolving for 250 years. Then it abruptly stopped developing toward the end of the fourteenth century. The people who created this art appear to have been without formal education. Estimates suggest that only some 40 percent of the master masons could even write their name on a document. They probably knew nothing of formal geometry, and it is unlikely they made any calculations. Most astonishing of all, they built without working drawRouen Cathedral ings. The medieval cathedral builder learned his empirical art (or should we call it empirical science?) through apprenticeship. The master builder had all kinds of tricks of the trade at his disposal, many of them jealously guarded. These tricks amounted to a vast inventory of knowledge of material selection, per-

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sonnel management, geometrical proportioning, load distribution, and architectural design, coupled with a firm sense of liturgy and Christian tradition. These builders saw no clear boundary between things material and things spiritual. Their art flowed from their right brain. It was visual and spatial. They levitated tons of stone in the air to communicate their praise of God, and when they were finished, they embellished the nooks and crannies and high aeries of their buildings with the phantoms of their minds— with cherubs and gargoyles and wild caricatures of one another. Gargoyle on the Sainte-Chapelle in Paris By the thirteenth century, they boldly and proudly identified themselves with their work. An inscription, twenty-five feet long, on the outside of the south transept of Notre Dame Cathedral, the one pointed toward the Seine River, says: Master Jean de Chelles commenced this work for the Glory of the Mother of Christ on the second of the Ides of the month of February, 1258. So what became of this marvelous art? The best guess is that it died when the master builder became an educated gentleman—when he moved into an office and managed the work of others at a distance. At that point the kind of hands-on creativity that had driven it so powerfully dried up. Still, the last great medieval cathedral was only recently completed— here in the United States. The National Cathedral in Washington, D.C., was built with great fidelity to both the style and the working esprit of the medieval art. This huge structure was finished after eightytwo years of construction, and it is breathtaking. If you ever visit Washington, don't miss the chance to see it. Eventually the Church-driven medieval world, with all its high technology, ran to the end of its tether. Overpopulation took its toll. Famines began visiting Europe in the late thirteenth century. Then, in 1347, the plague, caused by the bacterium Yersinia pesfis, swept out of Asia into a weakened Europe. Rats carried the disease off ships in

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Genoa. In just four years it killed a third or so of the people in Europe. It took three forms: Bubonic plague hit the lymph system, pneumonic plague attacked the lungs, and septicemic plague assaulted the blood. But the words Black Death encompassed it all. After 1351, the Black Death went from its epidemic phase, where the disease suddenly appeared, to its pandemic phase, during which it settled into the local environment and kept coming back every few years to whittle away at the population. From the first famines in 1290 until the plague pandemic began to recede in 1430, Europe lost over half its people. And that was after the disease had devastated the Orient. The Black Death is probably the greatest calamity our species ever suffered.5 What did the plague leave in its wake? For one thing, it unraveled the feudal system. It also left many survivors wealthy with the material goods and lands of those who had died. Manual labor became precious. Wages skyrocketed, and work took on a manic quality. When death rides on your back, time also becomes precious. It matters. The Church-centered world before the plague had been oddly timeless. Now people worked long hours, chasing capital gain, in a life that could end at any moment. The first new technologies of the plague years were mechanical clocks and hourglasses. Medicine had been the work of the Church before the plague. Physicians were well-paid, highly respected scholars. They spun dialectic arguments far away from unwholesome sick people—not unlike some of today's specialists. Fourteenth-century medicine, like the fourteenthcentury Church, had failed miserably in coping with the plague. Now both medical and religious practice shifted toward the laity. Medicine was redirected into experimentation and practical pharmacology. Medical and botanical books began to appear at the end of the fifteenth century, written not in Latin but in the vernacular, and by a whole new breed of people. Technology had to become less labor-intensive; it had to become high-tech. For good or for evil, the plague years gave us crossbows, new medical ideas, guns, clocks, eyeglasses, and a new craving for general knowledge. So the rainbow at the end of this terrible storm, all intermingled with the Hundred Years' War, yielded its pot of gold. The last new technology of this ghastly century and a half was the printing press. The new presses finally thawed the epoch that Shakespeare named the "winter of our discontent." They provided access to knowledge, and they started the rebirth of human energy and hope in Europe.

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But the brief bright period in which religion and technology had wed was now fragmented. From now on religion and our direct knowledge of the world around us would coexist under an increasingly uneasy peace. Take one example: Down through the centuries, many biblical scholars have tried to calculate the age of Earth. By the mid-nineteenth century a hundred or so such calculations were extant. They gave ages that ranged from fifty-four hundred to almost nine thousand years. Well before Darwin, geologists had begun insisting that the Bible was not really meant to give us this sort of technical data—that Earth is, in fact, much older. At first they had no basis for making their own estimates. Then, in 1862, the English scientist Lord Kelvin made the first numerical calculation of Earth's age based on data gathered outside the Bible. Kelvin knew Earths temperature increased one degree Fahrenheit for each fifty feet you went into the ground. He guessed that Earth began as molten rock at seven thousand degrees Fahrenheit. Calculating how long Earth would have to have cooled to establish that surface temperature gradient, Kelvin found that it must have taken a hundred million years for Earth's temperature to level out at one degree every fifty feet.6 From the viewpoint of contemporary scientists, Kelvin had opened himself up to assault when he used Fourier's equation to calculate transient heat conduction through the Earth. In 1807 Joseph Fourier had developed an equation for heat conduction that was based on avantgarde mathematics. Kelvin had to invent radical mathematical means to solve Fourier's equation since he did not know conditions deep inside the Earth.7 So now the fat was in the fire! The deeply religious and antievolutionist Kelvin had determined an age that was far too young to satisfy geologists and Darwinists. But it was plenty old enough to waken the ire of biblical literalists. The real problem with Kelvins estimate was that he did not know about radioactivity. Today we know that Earth's temperature variation is sustained by radioactive decay. That means Kelvin's cooling calculation could not possibly have given Earth's age correctly. Its real value lay in the intellectual stimulus it created. Of course his critics had no more knowledge of radioactivity than he did; the great Victorian scientists and mathematicians knew something was wrong, but it was unclear what was wrong. So they formed ranks to fight about questions of mathematical method and biblical exegesis. The debate went on until the

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twentieth century. It drew in Darwin, Huxley, Heaviside, and many more. When they were through fighting, at least mathematical heat conduction analysis had found a solid footing. Today, modern chemical analysis tells us that Earth is four and a half billion years old. But the debate over Kelvin's calculation helped to set up techniques by which engineers can solve far nastier heat flow problems than he ever could—techniques for determining everything from how long it takes to refrigerate fruit to a certain temperature to how to cool a brake shoe. I do not incline to be dismayed by this checkered story, for it becomes clear that we learn so much more when the path to understanding leads through briar patches like this one. It took historian Henry Adams to stand away from the nineteenthcentury science-religion quandary and put things in perspective by laying them out once more against the backdrop of the medieval Church. Our second president, John Adams, had sired a dynasty His son John Quincy was also president, and his grandson Charles was a congressman and ambassador to England during the Civil War. In his autobiography, The Education of Henry Adams, John Adams' great-grandson measures himself against his extraordinary forebears and finds himself wanting— even though he was a writer, congressman, and noted historian. Toward the end of the autobiography Adams portrays himself as a sort of everyman facing the juggernaut of twentieth-century science and technology. His chapter titled "The Dynamo and the Virgin" takes us through the great Paris Exposition of 1900. Adams was one of forty million people who visited its eighty thousand exhibits. He was drawn back day after day, trying to Four generations of the Adams understand it all. family. Adams' most important works of history up to that point had been studies of two medieval edifices: the abbey at Mont-Saint-Michel and Chartres Cathedral. They had led him to see the remarkable social impact of medieval Christianity, centered as it was on the Virgin Mary. Now he gazed at dynamos, telephones, automobiles—wholly new technologies that had sprung into being in just a few years and which were based on invisible new forces of radiation and electric fields. He saw that the dynamo would shake Western civilization just as surely as

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the Virgin had changed it eight hundred years before. His historical hindsight made him comfortable with the twelfth century, but the Paris Exposition was more than he could digest. His guide through much of the exposition was the aeronautical pioneer Samuel Pierpoint Langley. Langley was a down-to-earth physicist, willing to explain things in functional terms. But Adams was too intelligent to mistake the explanation of how something works for a true understanding of it. He says: "[I found myself] lying in the Gallery of Machines—my historical neck broken by the sudden irruption of forces totally new." Adams didn't mention two ideas that would complete the intellectual devastation before his autobiography was published: quantum mechanics and relativity theory. He probably did not know about either one, but, on a visceral level, he saw them thundering down the road. It was clear enough to Adams as he surveyed the exhibit that it portended a great unraveling of nineteenth-century confidence in science. In the end, Adams lamented the blind spot of his times, the denial of mystery. The Virgin was the mystery that drove the medieval technological revolution. He said, Symbol or energy, the Virgin had acted as the greatest force the Western world ever felt, and had drawn man's activities to herself more strongly than any other power, natural or supernatural, had ever done. Adams realized that the dynamo and modern science were ultimately being shaped by forces no less mysterious. Neither Langley nor anyone else understood radium and electricity, any more than Adams himself did.* History has proven Adams right. Nineteenth-century science and technology came out of the exhibition hall changed beyond recognition. The self-sufficient determinism of Victorian science was breaking up under his nose. By the time the implications of quantum mechanics were sorted out, science was as incomplete as ever. It was a chastened intellectual enterprise that left both the exhibit hall and the nineteenth century. We had come to understand that the Bible is not a book of scientific formulas. But during the twentieth century, we have also come to understand that science too is a glass that lets us only glimpse the mysteries of our being, and then only in part—only darkly.

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3 Looking Inside the Inventive Mind

n inventor—any creative person—knows to look under the surface of what things seem to be, to learn what they are. I have been able to find only one constant in the creative mind. It is that surprise is the hidden face of the coin of invention. In their operetta Pinafore, Gilbert and Sullivan warn us:

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Things are seldom what they seem, Skim milk masquerades as cream; Highlows pass as patent leathers; Jackdaws strut in peacock's feathers. For example, an engineer designing a highway system wants to include crossroads between the major arteries. Common sense says that crossroads will increase driver options and speed traffic. Only very keen insight, or a complex computer analysis, reveals that crossroads tend to make matters worse. They often create localized traffic jams where none would otherwise occur. We are caught off guard when common sense fails us. Yet it is clear we would live in a deadly dull world if common sense alone were sufficient to lead us through all the mazes around us. If what we learn is no more than what we expect to learn, then we have learned nothing at all. Sooner or later, every student of heat flow is startled to find out that insulation on a small pipe can sometimes increase heat loss. Common sense is the center of gravity we return to after our flights of fancy. But it is the delicious surprise—the idea that precedes expectation—that makes science, technology, and invention such a delight.1

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A wonderful old expression calls creativity "a fine madness," and it is. Invention lies outside the common ways and means. If it is sane to respond predictably to reality, then invention surely is madness. A wellknown riddle shows us something of the way that madness works. You are asked to connect nine dots, in a square array, with four straight lines. Each line has to continue from the end of the last line. The problem seems to have no solution. If, for example, you draw a sequence of lines on three sides, like this, then the fourth line would be either a diagonal that connects the center dot, or a horizontal line that connects the lower dot. You cannot get them both. The trick, of course, is to walk around accepted limitations. It is easy enough to connect the nine dots when we work without knowing the answer ahead of time. Once we recognize that lines need not conform to the square space suggested by the dots, we can solve the problem. The expression "thinking outside the box" probably comes from just this riddle. (Turn the page for the solution.) What kind of mind does it take to see through a question like this? Certainly not one that thinks "normally"! That's why creativity cannot be reduced to method. The best we can do is to meet a few of the great inventive minds and inventive acts. When we do that, we find some creative people adopting a camouflage of orthodoxy—focusing their creative power productively and living contentedly. Others have been savaged by the fine madness running amok in their lives. So let us flirt with this kind of madness. Let us gaze on some things that are not what they first seem to be. Let us meet some creative people and their acts of invention. Let us savor the delicious surprise that made it worth the cost of their travels through an alien land. Let us begin with the story of Christopher Wren and the dome of Saint Paul's Cathedral. When I was young in St. Paul, Minnesota, I would take the streetcar

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downtown. It would rattle past a great cathedral with a lovely big dome. The name of that cathedral was both the name of the city and the name of the great English cathedral that it copied—St. Paul's in London. No child of World War II can forget movies showing St. Paul's dome standing out against London's bomb-lit night sky. It survived the blitz even though it had been rebuilt repeatedly since A.D. 607. In 1665 it was a five-hundred-year old Gothic cathedral, never really finished and falling apart. The brilliant young architect Christopher Wren was told to rebuild the old wreck. He put a radical plan before the cathedral planning commission: He would tear down the old Gothic building and replace it, capping the new building with a dome like the ones on Renaissance churches in Europe. The commission would have none of that. Cathedrals had spires, not domes. St. Paul's would be patched, not rebuilt, and Wren would place a new spire upon it. Wren rankled for a year. Then nature intervened. The terrible Great Fire of 1666 finished off the old building, and Wren was free to design a new one. The commission still rejected his dome, even though King Charles rather liked it. Finally the king gave Wren a loophole. He told him to erase the dome from his plans and draw in a steeple—any steeple. Then the king put a phrase in Wren's contract that granted him "liberty to make such variations as from time to time he should see proper." Wren topped his design with a hideous, out-of-proportion steeple, satisfied the commission, and went to work. It took thirty-five years to build the new cathedral—far longer than the collective memory of any committee. As the structure rose, Wren made a careful sequence of changes. The bogus steeple gracefully gave way to a marvel of engineering: a great dome, no feet across, soaring 368 feet into the air. To hold it without buttresses, Wren girdled it with a huge iron chain hidden by the facing stone. (That old, rusted chain was finally replaced with stainless steel in 1925.) Today you can still go to London, sit in a pew, and see what ninetytwo-year-old Christopher Wren saw on the last Sunday of his life—an interior that seemingly stretches to infinity in five directions, north, south, east, west, and up. The view upward, past the whispering gallery to that splendid ceiling, is hard to forget. When Wren died, they buried him in the cathedral under a small plaque. The building itself is his monument. It is also a monument to the will of this gentle genius who found a way to show people what could not be explained to them.2

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So we begin with an exemplary case—a man who, like his medieval forebears, found fine constructive means for living in the world of rough-and-tumble with his creative daemon at his side. We find similarities in the story of Benjamin Thompson, but Thompson's means for coping with the daemon reveal harder edges than Wren's did. Thompson was raised in Woburn, Massachusetts, in the years of the gathering American Revolution. He wrestled out a homemade education in Boston and, when he was only eighteen, went off to Rumford, Massachusetts, as the new schoolmaster. He soon married a wealthy thirty-one-yearold widow. Then he took up spying on the colonies for the British. When the colonists found out what he was doing, he deserted his wife and baby daughter and fled to England. Thompson devoted the next several years to shameless social climbing that eventually put him in a high-ranking position with the Bavarian court in Munich. Here his life took on a different coloration. He boldly combined technical insight with social reforms that were years before their time. He instituted public works, military reforms, and poorhouses. He equipped public buildings with radical kitchen, heating, and lighting systems. As a part of a lifelong interest in heat and its management, he gave us the Rumford stove. And why Rumford? Therein hangs the rest of his story. In 1792 he was made a count of the Holy Roman Empire and he took the name of the town of Rumford. Thompson is best remembered as Count Rumford and for the experiments he made under that name five years later. His interest in field artillery led him to study both the boring and the firing of cannons. There he saw that mechanical power could be converted to heating, and that there was a direct equivalence between thermal energy and mechanical work. People at the time thought that heat energy was a fluid—a kind of ether called caloric—that flowed in and out of materials. Caloric could not be created by mechanical work or by any other means. Rumford's results flew in the teeth of the caloric theory. They showed that you can go right on creating caloric as long as you have a source of mechanical work. He also showed that when you fired cannons without a cannonball in the barrel, they heated up more rapidly than when you fired

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them loaded. When the cannonball was there, heat was converted to the work of accelerating it. Rumford's story eventually took a last, ironic turn. Caloric had been given its name by the famous French chemist Lavoisier, who was beheaded during the French Revolution. When Rumford returned to England and France, he became involved in a fouryear relationship with Lavoisier's widow. Their affair ended in a disastrous and shortlived marriage. Before the marriage Rumford crowed, "I think I shall live to drive caloric off the stage as the late Lavoisier drove away phlogiston. What a singular destiny for the wife of two Philosophers!!" Count Rumford was indeed instrumental in driving caloric off the stage. But can it be any surprise that the marriage failed?3 Rumford clearly had at least some dimension of control over the daemon. But many people have none. A young man born in France in 1811, three years before Rumford died in France, is a fine case in point. He was Evariste Galois, the father of modern algebra. Galois died of gunshot wounds at the age of twenty years and seven months. He was still a minor when his brief, turbulent life ended. He began a career in mathematics by twice failing the entry exam for the Ecole Polytechnique because his answers were so odd. He was finally accepted by the Ecole Normale, only to be expelled when he attacked the director in a letter to the newspapers. A few months later he was arrested for making a threatening speech against the king. He was acquitted, but he landed right back in jail when he illegally wore a uniform and carried weapons. He spent eight months there, writing mathematics. As soon as he got out, he was devastated by an unhappy love affair. It might be fair to say he was a typical bright young teenager. For some murky reason—perhaps it was underhanded police work— he was challenged to a duel on May 30,1832. It was a duel he could not win, but which he could not dodge either. By then his talents as a mathematician were known. He had published some material, and outstanding mathematicians including Gauss, Jacobi, Fourier, and Cauchy knew of him. On May 29 he wrote a long cover explaining the hundred or so pages that he produced during his entire short life. He set down what proved

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to be the foundations of modern algebra and group theory. Some of his theorems were not proven for a century. He faced death with a cool desperation, reaching down inside himself and getting at truths we do not know how he found. His fright and arrogance were mixed. The letter was peppered with asides. On one hand, he wrote: "I do not say to anyone that I owe to his counsel or.. .encouragement [what] is good in this work." On the other hand, he penned in the margins, "I have no time!" When poet Carol Christopher Drake heard his story in 1956 she wrote: Until the sun I have no time But the flash of thought is like the sun Sudden, absolute: watch at the desk Through the window raised on the flawless dark, The hand that trembles in the light, Lucid, sudden. Until the sun I have no time The image is swift, Without recall, but the mind holds To the form of thought, its shape of sense Coherent to an unknown time— I have no time and wholly my risk Is out of time; I have no time, I cry to you I have no time— Watch. This light is like the sun Illumining grass, seacoast, this death— I have no time. Be thou my time.4 The next morning Galois was shot, and two days later he was dead; his creative daemon had killed him. Still, he had done more for his world in one night than most of us will do in a lifetime, because he knew he could find something in those few moments when he had to reach down and look deeply inside himself.

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Mathematics, of course, is terribly demanding. To do mathematics and to do it well requires enormous mental discipline. Some have the technical discipline without having the supporting emotional self-control. That fact came home to me the day a colleague pressed me to write a radio program about Georg Cantor. I began looking closely at Cantor and was immediately reminded of a Time magazine article my father had read to me when I was in grade school. The article snatched my imagination. Someone proposed a new number called the googoL The googol was ten to the hundredth power— a one followed by a hundred zeros. Later I learned that it would be of little help in counting real objects, because we are hard pressed to find that many real objects in the whole universe—even atoms. Still, where does counting end and infinity begin? There is good reason to ask about infinity. Every engineering student knows that infinity is not just the end of numbers. If we ask how real systems behave when velocities, time, or force becomes infinite—if we ask about the character of infinity—we get some unexpected answers. The mathematician Georg Cantor also wondered about infinity. He was born in Russia in 1845. He wanted to become a violinist like his mother, but his father, a worldly merchant, wouldn't have it. When he was seventeen, his father died. Cantor went on to finish a doctorate in math in Berlin when he was only twenty-two. His career was not long—he burned out before he was forty and spent the rest of his life in and out of mental illness. But what he did was spectacularly important, and it arose out of an innocent counting question. He began with an idea we find even in Mother Goose. Remember the rhyme "One potato, two potato, three potato, four. Five potato, six potato, seven potato, more?" Counting is like matching one set of things with another—in this case, numbers with potatoes. Cantor asked if counting all the infinite number of points on a line was like counting all the infinite number of points in a surface. To answer the question, he had to invent something called transfinite numbers. He identified orders of infinity. If you simply count the integers, you obtain the first order of infinity. Raise two to that power and you get the next order of infinity, which happens to be the number of sets you can form from the lowest order of infinity, and so forth. To sort through all that, he had to invent set theory, which has become a basic building block of modern mathematics. Cantor fell into an odyssey of the mind—a journey through a strange

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land. He had to overcome the resistance of his father, of the great mathematicians, and even of his own doubts. When he was thirty-three he wrote: "The essence of mathematics is freedom." To do what he did, he had to value freedom very highly—freedom coupled with iron discipline, freedom expressed through the driving curiosity of a bright child, freedom to pursue innocent fascination until that fascination finally changed our world. Cantor lived his troubled life until 1918—long enough for him to see set theory accepted and himself vindicated for his soul-scarring voyage of the mind.5 But Cantor's and Galois' cases are extreme. While stories like theirs abound, the telling of them can lead us away from the better aspects of the creative process. Let me offer a third mathematician/engineer/scientist whose story has a completely different flavor—or perhaps I should say a peculiar lack of any flavor at all. Let us meet Josiah Willard Gibbs. Historians dislike superlatives. It is too easy to be wrong when you use words Hkefirsf and best. Yet I am completely comfortable saying that Gibbs was the greatest American scientist who has ever lived. Gibbs was born in New Haven, Connecticut, in 1839. He was the seventh in an unbroken line of American academics, stretching all the way back to the seventeenth century. His father was a noted professor of linguistics at Yale University. He lived his entire life in the same house and died there in 1903. What did Gibbs do? He created the entire subject of chemical thermodynamics; he gave us the subject of vector analysis; he invented statistical mechanics and developed it as far as it would go before quantum mechanics could take it further; and he did basic work in several other areas. Other great scientists contribute to fields. Gibbs created three entire fields— pulled them out of his empyrean mind and gave them life. He did little to invite fame. He hardly traveled; he did not collaborate; he never married; and he published most of what he wrote in the obscure Transactions of the Connecticut Philosophical Society. Outwardly, he was dry and colorless. Gibbs studied at Yale, where he earned one of the first doctorates offered in the United States. He was America's very first Ph.D. in mechanical engineering. His thesis dealt with shaping gear teeth. After that, he taught at Yale and worked on the design of railway equipment, particularly brake systems. From 1866 to 1869 he studied mathematics and physics in Paris, Berlin, and Heidelberg. That was the only real trip

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he ever took. He was thirty-four before he published his first paper, and it was still later that his abilities started to become apparent. When his work on thermodynamics attracted attention, the Johns Hopkins University offered him a position. Up to then, Yale had not been paying him. Now, at least, Yale put him on the payroll. Gibbs' work is spatial—like good engineering work. It moves in a surrealistic, multidimensional landscape. People who join him in his voyage of the mind find it seductively beautiful. Since his death, twentieth-century scientists have peeled him like an onion, and under each layer they have found what they had missed under the previous one. J. Willard Gibbs' life was wrapped in plain gray—faculty meetings, committees, classes. He lived as a quiet professor doing commonplace things. He received no major grants, no Nobel Prize. But it was his edifice that Einstein and Fermi completed. He rewrote science. He changed history. And I can assert with a bland certainty that he was our greatest scientist.6 Gibbs is a curious case in that he offers almost no guidance whatsoever as to how you and I might reach for the brass ring of creativity. I can only lay him out before you and say, "Make of him what you will." For guidance, we must look elsewhere. So let us return to the remark we made at the outset—the observation that creativity is surprise. This means seeing ideas out of context. The creative process must include an ability to recognize the stray idea out on the far fringe of our peripheral vision. Consider that our knowledge of microbes is just over three hundred years old. They were first observed in the late seventeenth century by the Dutch lens maker Antonie Van Leeuwenhoek. He called these small creatures animalcules, and he realized that they swam in any body of water. But what about relating these small beasts to disease? One hundred and fifty years later, disease was rampant in London. Half the newborn babies died, and the death rate was far higher among the poor than among the wealthy. Two things had become clear by then. One was that London's drinking water was, by and large, loaded with microorganisms. The other was that filth—particularly raw sewage— was to be found everywhere in poor areas. It is obvious to us that germs were causing the diseases. But germs, after all, swam in waters drunk by both the well and the sick. It was obvious that bad smells were found in unhealthy neighborhoods, and it seemed clear that stench, or miasma, as it was called, caused disease. No

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one had cause to worry about the water. It was the stink that people felt they had to eliminate. Then, in 1849 and 1853, London suffered terrible epidemics of cholera. In 1853 a physician named John Snow began looking at statistics. He worked doggedly among the sick and kept meticulous records of who had died and exactly where they had lived when they fell ill. It took a long time, but Snow eventually found a high incidence of cholera among people who had been drawing water from a source called the Broad Street well. That made no particular sense until Snow realized that the cesspool of a tenement occupied by a cholera patient was adjacent to the well. Contaminated water had been leaking from the cesspool into the groundwater picked up by the well. Over protests, he managed to remove the handle from the well, and cholera abated in that part of London.7 Snow's report soon led people to see that cholera was caused not by noxious gases but by what came to be called feca/ized water. He put people on the track of the real disease agent. Four years later, Louis Pasteur connected disease to bacteria. And in 1865 Joseph Lister found that he could kill disease-carrying bacteria during surgery by spraying a carbolic acid solution over the patient. Finally, in 1882, a scant twenty-nine years after Snow pinpointed the Broad Street well, the German physician Robert Koch showed how to make a disease-specific vaccine. He had found the bacterium that caused anthrax and figured out how to make a vaccine to prevent it from infecting animals. It can take decades for people to overturn old thinking. The leap from unhealthy vapors to bacteria was still a hard one to make, even once Snow had used the Broad Street well to show that a leap had to be made. Making that leap, of course, reminds us that no accounting of the creative process is complete without an eccentric-scientist story, even if such tales miss the point. Creativity, after all, is always eccentricity. It can be no other way. But in the interests of completeness, let us meet the eccentric Nikola Tesla. When I worked in Yugoslavia back in 1974, I especially liked their five-hundred-dinar notes. In that economy, they were a kind of thirtydollar bill with a picture of a lean man reading from a large book. The man was Nikola Tesla—one of the early geniuses of electricity. Tesla was born in Serbia and educated in Prague. He came to the United States in 1884, when he was twenty-eight years old.

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Tesla had by then revealed a wild mercurial talent for manipulating the mysterious new forces of electricity, and he carried a letter of introduction to Thomas Edison. The already famous Edison would probably have shrugged him off, but he was shorthanded when Tesla showed up. The new electric lighting system in the steamship Oregon was failing, so he hired Tesla on the spot and sent him off to fix it. Tesla did fix it, but he lasted less than a year with Edison. Edison took Tesla for an egghead, a theoretician, and an epicurean snob. Edison said that 90 percent of genius was knowing what would not work. Tesla called that kind of thinking an "empirical dragnet." He complained, If Edison had a needle to find in a haystack he would proceed at once with the diligence of a bee to examine straw after straw until he found [it]. I was a sorry witness of such doings,... a little theory. . .would have saved him ninety percent of his labor.8 Tesla was a dapper bon vivant, six and a half feet tall. He spent every cent on the good life. He cultivated rich and famous friends, people such as Mark Twain. He wrote poetry and spoke half the languages of Europe. But he never married. In fact, he could not bear physical contact with other people because he had a terrible phobia about germs. He eventually found his way to George Westinghouse, to whom he gave the concept of alternating current. That led to open combat with Edison, who clung to direct current long after it was clear he was riding the wrong horse. But Tesla was not just the father of the alternatingcurrent power that serves your home. He also demonstrated the concept of the radio before Marconi did. He invented the "Tesla coil," a resonant transformer that generates spectacular million-volt sparks. He was the electrical showman of the late nineteenth century, dazzling audiences with brilliant electrical displays. The unit of magnetic-flux density was named after Tesla, yet he never published a technical paper. Lord Rayleigh once told him to settle down and specialize like a proper scientist. That was poor advice for the wild Serbian cowboy who rode behind Tesla's urbane front. Tesla played counterpoint to Rayleigh's orthodoxy just as he did to Edison's dogged trial-and-error methods. Edison and Rayleigh were great men indeed, but Tesla reminds us once more that there is no formula for calling up the muse of invention. It is something that ultimately might be impossible to teach.

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So what of the people who attempt to teach engineering? How do they awaken the creative genie? Well, sometimes they do and sometimes they don't. Let us meet two men who were exemplars in very different ways. What was it that they did right? First I give you Max Jakob. In 1937 Jakob and his family boarded the steamer Eerengaria in Cherbourg, Mark Twain (Samuel Clemens) doing a high-voltage experiment in France, to make a stormy six-day Nikola Tesla's laboratory, from Century Magazine, April 1895. crossing to New York. The Jakobs were leaving their German homeland for good. Max Jakob limped slightly as he walked up the gangway, the result of a wound on the Russian front in World War I. He was now fifty-eight years old and a prominent German expert in the field of heat transfer. For thirty-one years, ever since he had finished his doctorate in Munich in 1906, Jakob had worked on central questions of the thermal sciences, and he had been involved with the greatest scientific minds of his era. His daughter, Elizabeth, showed me some of the remarkable items from his correspondence. A postcard from Einstein (who was born and died within months of Jakob) indicates his gratitude to Jakob for setting a critic straight on relativity. A letter from Max Planck thanks Jakob for correcting an error in his paper. But now Jakob had to board a boat to America. Four years before, German troops had gone through Berlin painting the word JEW in large white letters on store windows; Jakob wrote in his diary, "I never valued my Jewishness as much; but today I'm happy not to be on the side of those who tolerate this." First he sent Elizabeth to college in Paris. Then he and his wife prepared to leave what seemed the intellectual and cultural center of the universe. They were moving to the land of gangsters and Al Capone—to Chicago, whose climate, he had been told, was murderous. Each of them was allowed to take four dollars out of Germany. Jakob's move proved terribly important for America. We were far behind Germany in understanding heat flow and were working hard to make up ground. Jakob gave us the first direct conduit to that knowl-

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edge. His students formed a cadre that practically defined the field from the 19505 through the '705. And America was a pleasant surprise for Jakob. The first photographs show him smiling and inhaling the fresh air of a new land. Once here he discovered, and took pleasure in, civilization of a different form, but civilization nevertheless. He found youthful excitement in the intellectual climate, and he became a part of it. He gave every bit as much as he got. Many of today's elder statesmen in the field were his students, and everyone in the field knows his work. In a diary entry the week before his death, in 1954, he writes about hearing the great contralto Marian Anderson sing. He was deeply moved by her singing of "the magnificent Negro spirituals, especially 'Nobody Knows the Trouble I've Seen' and 'He's got the Whole World in His Hands.' " By then America had claimed its day as the world leader in heat transfer. Jakob and his many students had helped us so much to get there. He finished his life as one of the great American engineers and educators. The story of Llewellyn Michael Kraus Boelter has a completely different flavor than that of Max Jakob. Only the qualities of steadiness and evenhandedness bind the two together. Both men worked primarily on problems of heat transfer, making use of those physical laws that govern the flow of heat. Those laws were known by the beginning of this century, but there is a great gulf between knowing raw physical laws and knowing how to make them serve a world that is hungry for energy. In 1900 it was practically beyond us to calculate heat flow in most situations. Then German engineers began to develop the mathematical means for using these laws. By the 19205 they had made great strides, and America, by comparison, was far behind. That all changed by World War II, and the person who contributed the most to this change before Max Jakob moved here was Boelter. Boelter was born in 1898 and raised on a Minnesota farm. He graduated from the University of California at Berkeley and then stayed on as a faculty member. There he gave us all a lesson in how to teach engineers. His method was simple. He went directly to the student's mind. Nothing got in the way, least of all himself. He taught students to go to the unanswered question—to attack their own ignorance. He directed their efforts into the study of heat transfer. He drew people in, and together they opened up the German literature. Then they kept right on moving while the German work was being ended by Nazi repres-

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sion. By the early 19305 they had created a new American school of heat transfer analysis. Knowledge was the great equalizer for Boelter. He and the people around him used last names—no titles. Even Berkeley's catalog listed everyone as Mr. The unanswered question was the only absolute taskmaster, and he made sure his students faced questions that led them where they had not been before. He saw to it that it was his students, more than he, who went on to become the international leaders in the field. He went to UCLA as dean of engineering in 1944, and he made a great learning laboratory of the place. He abolished departments. Were you an electrical engineering professor? Fine, this term you would teach a civil engineering course. That way knowledge stayed fresh—learning stayed alive. In 1963 he spoke to the UCLA freshmen. His words look repetitive on the written page, but then you catch their antiphonal rhythm—with the lines alternating the first word you and and. Coming from this quiet man, they have an astonishing intensity and an unexpected moral force. He said: The products of your mind are the most precious things you own, that you possess. And you must protect them, and must not do wrong with them, you must do the right thing. You must always have in mind that the products of your mind can be used by other people either for good or for evil, and that you have a responsibility that they be used for good, you see. You can't avoid this responsibility, unless you decide to become an intellectual slave, and let someone else make all of these value judgments for you. And this is not consonant with our democratic system in this country. You must accept the responsibility yourself, for yourself, and for others.9 Boelter really saw the transcendence of thought—of the "products of the mind." He saw their power to change life. He understood that they bind us to responsibility, but that they also set us free. Boelter was, in essence, giving his students advice on how to control the creative daemon who sits at our side when we function creatively. Now let's look at another kind of case history—one about the creation of the daemon itself. It is a story that began as the summer of 1896 drew to a close. Orville Wright had caught typhoid fever, and his older brother, Wilbur, sat at his side, nursing him as he hovered at death's door for six weeks. Sixteen years later Wilbur caught typhoid, and it

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killed him. In between, of course, the two brothers created the first workable airplane. Before Orville fell ill, newspaper articles about Otto Lilienthal, the German pioneer of flight, had deeply impressed the brothers. Lilienthal built and flew gliders until he died in a crash in 1896, the same year Orville almost died. Later, Orville claimed that Wilbur read about Lilienthal's death while he was ill and had withheld the terrible news until he recovered. The story may have been distorted by time, as Lilienthal actually died a month before Orville fell ill. What it really tells us is that the two powerful events of Lilienthal's death and Orville's recovery were linked in the Wright brothers' minds. Lilienthal built gliders for six years. Other people had made gliders before he did, but no one had made repeated successful flights. He started by imitating birds with flapping wings. Then he dropped that idea and went to a kind of fixed-wing hang glider. He made many different kinds of gliders: monoplanes, biplanes, and airframes of every conceivable shape. In six years' time, Lilienthal had made two thousand flights, and he was starting to think about powered flight. But then, one Sunday afternoon, a crosswind caught him fifty feet in the air. The glider sideslipped, crashed, and broke Lilienthal's back. According to legend, before he died, he murmured, "Sacrifices must be made." The trouble is, he had said that before. It was a typical Victorian sentiment, ai\d Victorian sentiment almost certainly tied the remark to his death. In 1900 Wilbur Wright wrote a letter to the next great glider pioneer, Octave Chanute, asking for advice. In the oddest way, his language evoked both Lilienthal's death and Orville's illness four years earlier. Wilbur wrote: I have been afflicted with the belief that flight is possible.... My disease has increased in severity and I feel that it will soon cost me...increased money...if not my life. Well, it was disease and not his belief in flight that eventually killed Wilbur. But the most elusive quest in the world is the search for the origin of an idea. The Wrights com-

Otto Lilienthal in flight.

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bined invention with remarkably thorough study and laboratory work. They worked methodically and inexorably for years, and their powered flight in 1903 rested upon that labor. But it also went back to summer s end in 1896—to a time when Lilienthal died and Orville lived, to a time when two brothers became certain of what they were destined to do.10 Victorian sentiment colored descriptions of invention in the late nineteenth and early twentieth centuries. We still find its echoes in accounts of the invention of the vacuum tube. Perhaps by making theater of invention we actually provide an avenue into invention. The story of the vacuum tube begins with the Edison effect. That was the name given to a phenomenon that Edison observed in 1875, although it had been reported two years earlier in England. Edison refined the idea in 1883, while he was trying to improve his new incandescent lamp. The effect was this: In a vacuum, electrons flow from a heated element, such as an incandescent lamp filament, to a cooler metal plate. Edison saw no special value in it, but he patented it anyway; he patented anything that might ever be of value. Today we call the effect by the more descriptive term thermionic emission. The magic of the effect is that electrons flow only from the hot element to the cool plate, but never the other way. Put a hot and a cold plate in a vacuum and you have an electrical check valve, just like check valves in water systems. Today we call a device that lets electricity flow only one way a diode. It was 1904 before anyone put that check valve action to use. Then the application had nothing to do with lightbulbs. Radio was in its infancy, and the British physicist John Ambrose Fleming was working for the Wireless Telegraphy Company. He faced the problem of converting a weak alternating current into a direct current that could actuate a meter or a telephone receiver. Fortunately, Fleming had previously consulted for the Edison &. Swan Electric Light Company of London. The connection suddenly clicked in his mind, and he later wrote, "To my delight...! found that we had, in this peculiar kind of electric lamp, a solution." Fleming realized that an Edison-effect lamp could convert alternating current to direct current because it let the electricity flow only one way. Fleming, in other words, invented the first vacuum tube. By now, vacuum tubes have largely been replaced with solid-state transistors, but they have not vanished entirely. They still survive in such modified forms as television picture tubes and X-ray sources. Fleming lived to the age of ninety-five. He died just as World War II

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was ending, and he remained an old-school conservative. Born before Darwin published his On the Origin of Species, he was an antievolutionist to the end. Yet even his objection to Darwinism had its own creative turn. "The use of the word evolution to describe an automatic process is entirely unjustified," he wrote, turning the issue from science to semantics. In an odd way, semantics marked FlemJtyJ ing's invention as well. He always used the term valve for his vacuum tube. In that he reminds us that true inventors take ideas out of context and fit them into new contexts. Fleming stirred so much together to give us the vacuum tube—not just lightbulbs and radio, but water supply systems as well.11 The theater in Fleming's discovery lies in his own account of it. Yet what he dramatizes is a process we have already talked about. The creative inventor takes ideas out of their original contexts and uses them in new ones. He turns bread mold into penicillin, coal into electricity, or, I suppose, lead into gold, because he is not constrained to keep each thought in its own container. J.A. Fleming's 1904 patent drawing. Another inventor, Thomas Sopwith, offers little theater. He was solid and workmanlike all his long life. The drama of Sopwith's life is cumulative, apparent only when we look back over our shoulder at what he accomplished. But let us go back to the beginning for his story. The airplane that finally brought down the "Red Baron," von Richthofen, was an English biplane called the Sopwith Camel. Camels were maneuverable little airplanes, and my father, who flew them in France, told me they were tricky to fly. But with a good pilot, they were deadly in combat. In 1916 the Germans controlled the air over the Western Front. The Sopwith Camels challenged their dominance when they arrived in France in 1917. They were given the name Camel because the contour of the fuselage included a humplike cowl over the guns, in front of the pilot. And Thomas Octave Murdoch Sopwith manufactured them. Sopwith was fifteen when the Wright brothers flew. He learned to

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fly in 1910, when he was twenty-two. By then, he had raced automobiles and speedboats, and he had done daredevil ballooning. In no time, he won flying prizes, and he used the prize money to start making airplanes. He was twenty-four when World War I was brewing. His first planes were used early in the war, and when the Sopwith Camel gave the air back to the Allies in July 1917, Sopwith was still under thirty. He stayed with airplane manufacturing after the war. In 1935 he was made chairman of the Hawker-Siddley Group, and there he did a most remarkable thing. In 1936 he decided to produce a thousand Hawker Hurricanes on his own, without a government contract. War was brewing again, and if the British government was not ready, at least Sopwith was. Without his Hawker Hurricanes, England would have been laid bare by the Nazi bombers during the Battle of Britain. But that was far from the last of Sopwith. After World War II he was involved in developing the Hawker Harrier—the first jet airplane that could take off and land vertically. The Harrier was quite prominent during the Falklands War. Sopwith celebrated his hundredth birthday on January 18,1988. The RAF sent flights of Sopwith's airplanes over his home near London: an array of airplanes from early flying machines to modern jets! It was a parade that represented the whole history of powered flight during the life of this remarkable man, who had an uncanny ability to read the future. He died a year later, at the age of ioi.12 So where do inventive ideas come from? Sopwith's life no more answers that question than Gibbs' life does. However, it is worth looking at two stories that include intimations of how inventors found their way to invention. We shall begin the first with the Sperry-Rand Corporation trying to sue Honeywell in 1967. Honeywell was making digital computers, and Sperry claimed that Honeywell owed them a royalty. After World War II, Sperry had bought the patent rights to ENIAC, the first digital electronic computer. Honeywell countersued Sperry. They made the extraordinary claim that Sperry's patent was invalid—that the digital computer had been invented before ENIAC. Honeywell won its case six years later, and they did it by correcting history. People at Honeywell found their way back to the winter of 1937. John Atanasoff, a young physics instructor at Iowa State University, was struggling with the problem of mechanizing computation. Things were going badly this particular evening. Finally, in frustration, he jumped in

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his car and sped off into the night. Two hundred miles later, he pulled up at a roadhouse in Illinois to rest. There it came to him. A machine could easily manipulate simple onoff electrical pulses. If computations were done in the either-or number base of two, instead of the conventional base ten, a machine could do calculations naturally. Sitting in that roadhouse, two hundred miles from home, he made the crucial step in inventing the digital computer. Two years later, Atanasoff and a colleague named Berry started to build a computer. But in 1942 they were drafted, and the almost-complete computer was set aside without being patented. Meanwhile, the government started work on the ENIAC digital computer, which differed in some ways from Atanasoff and Berry's machine and in any case was bigger. An unfinished, unpatented machine does not make a very strong claim in a priority dispute. But in this case there was a catch. One of the major inventors of ENIAC, John Mauchly, had known Atanasoff. Not only had they corresponded, but Mauchly had even visited Atanasoff in Iowa for a whole week in 1941. In the end, it was clear that the ideas that resulted in ENIAC actually were Atanasoff's. Atanasoff did all his work with only six thousand dollars in grant money. But the military funded the ENIAC project. They were interested in making artillery firing tables, and they put a half million dollars into ENIAC. That was a huge sum in 1942. So the next time you turn on your PC, the next time you spend thirty seconds doing some task that would have taken your mother or father all afternoon, think about a man clearing his mind one winter night in 1937. Think about a man gazing at a yellow line for five hours, until— suddenly—he was able to see through the dark. The other story has to do with the problem of firing a gun—a cannon—from the deck of a rolling ship. In the War of 1812 warships fired banks of guns, broadside, at a nearby enemy. Seventy-five years later, ships carried long-range guns that fired from turrets. Aiming broadsides from rolling ships had been hard enough, but hitting a target a mile away was a whole different order of difficulty. In a typical test made in 1899, five American ships took turns firing at a ship hulk a mile away. After twenty-five minutes they had scored only two hits. By this time, ships' guns had telescopic sights and mechanisms that let gunners move them fairly quickly. The standard drill was to set corrections for the range, aim the gun roughly, then wait until the ship's roll put the target in the sights.

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In 1898 an English admiral, Percy Scott, watched his men at target practice. All but one was doing miserably. That one gunner had evolved his own aiming tactic. He kept his eye on the sight and he moved the gun continuously until he could feel the synchronization between his aim and the motion of the ship. What he was doing was subtle, yet it took advantage of skills that most people already had. It coupled the man and the machine. Scott adopted this technique and quickly set remarkable records in marksmanship. In 1900 an American naval officer, William Sims, met Scott in the Far East and learned all about his new technique. By 1905 the continuous-aim firing method had become standard U.S. Navy practice, but not before Sims had learned a grim lesson about innovation in organizations. Sims' attempts to interest the U.S. Navy in continuous aiming initially met a brick wall. English equipment, he was told, was no better than ours. If the men could not hit the target, it was because their officers did not know how to train them. And they told Sims flatly that continuous-aim firing was not possible. Sims finally went straight to Teddy Roosevelt, who recognized something in him and decided to give him a try. He abruptly made Sims the chief inspector of target practice. By 1905 a single gunner scored more hits in a one-minute test than the five ships had previously done in twenty-five minutes.13 That unknown English sailor thought not about mastering standard technique but about how to do the job. Scott recognized the importance of what he had done. And Sims championed the idea. Today, we ask ourselves how to shorten those three steps toward putting a good idea into play. How do we escape the mental straitjackets that keep us from seeing new possibilities? How do we give organizations the capacity to recognize value in invention? And how do we show people what that creativity can do for them? Not one of those tasks is easy. And we are back at our opening premise—that invention is a willingness to be surprised. For all three steps require that we open ourselves up to surprise, and that is surely one of the hardest things to do.

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4

The Common Place

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contradiction swirls around invention. While invention flows from an uncommon quarter of the mind, it ultimately comes to rest in the day by day world where we live our lives. Invention defines the commonplace world that we all share. The creative imperative is a unique and wonderful thing, yet it grows in the common clay of coping and of play, and that is also where it comes to rest. We celebrate the magnificent steam engines, airplanes, and cathedrals. But look around your room for a moment. When I do that I see paper, windowpanes, wood screws, a pencil sharpener, paint, and carpeting. Everything but the cat sleeping on the window ledge came into being after long sequences of invention by many people. Even the cat's subtle gestures and communications maybe partly the stuff of my own contrivance. When we look with the eye of the mind at the everyday world around us, we see how much human imagination has run riot through it. We realize how imagination has invested the basest elements of our lives with possibilities. Try counting the cost of the ordinary world in the coin of human ingenuity. Cartographers who invented the globe on my bookshelf gave me a way to visit Fiji, Chad, and Tibet—places where fortune is unlikely to take me. The simple crank mechanism on my pencil sharpener represents a huge leap of the mind that took place only about twelve hundred years ago (a matter we talk about in Chapter n). Imagination has enriched every corner of those common places where we all live out our lives. For example, a hassled secretary hacks out a living on a new IBM typewriter in 1951. The typewriter's ribbon ink leaves nasty smudges

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when she erases an error. In a burst of creative frustration, she goes home and invents a liquid for painting out mistakes. Its base is white tempera paint, the woman's name is Betsy Nesmith, and the liquid is an immediate hit with other typists. By 1956 she is running a cottage industry, mixing the brew for other secretaries. She calls the stuff Mistake Out, and her small son Michael (later to become one of the original Monkees) helps her fill hundreds of bottles a month. By the time the number stretches into thousands per month she renames the product Liquid Paper. Then one day her mind wanders at work and she types The Liquid Paper Co. on a company letter. Her boss fires her, but no matter. The Liquid Paper Co. is putting out twenty-five million bottles a year when she retires as Chairman of the Board in 1975. Another invention helps us see just how imagination interacts with the common place. To find the leap of the mind represented by the bicycle, we recall how psychologist Jean Piaget questioned young children struggling to understand it. Four year olds see the bicycle as a whole—a thing that goes entirely of itself. We listen as Piaget talks with a child: How does this bicycle go? With wheels. And how do the wheels turn? The bicycle makes them turn. How? With the handle-bar. How does the handle-bar make the bicycle go? With the wheels. And what makes the wheels turn? The bicycle. The child calls parts into the explanation and drops them just as quickly—for the bike is entire unto itself. When children reach six, they start referring to parts, but not in any orderly cause-and-effect way. You hear things like: What makes the chain turn? The wheels. What makes the wheels turn? Those brake wires.2

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The six-year old is just starting to forge understanding by breaking the bicycle down into its component pieces. Most children are nearly nine before they can sketch a bike from memory and explain how the parts work. Piaget's children and their bicycles reflect the same circuitous process by which the inventor first created the bicycle. Piaget demonstrates how we replicate the inventor's original thinking as we learn to analytically decompose things into cause-and-effect sequences. As inventors, we must see more than decomposed parts. We must also be able to put the parts back into a whole. We must be able to find our way back to the thinking that once marked our childhood, but, once we have, the truest answer to the question of how a bicycle works is that we and the machine become a single thing. Invention builds a bridge between analytical decomposition and the unity of the finished thing. The inventor must, at last, forget the wheels, chain, and sprocket of this wonderful device and, finally, sail down the road—riding the wind. So imagination makes the common sand in our lives into pearls by rekindling a childlike ability to see the world in a common grain of sand. Look at the things around you that you might never have regarded as having been invented. Some are so elemental that you would think they had been around before the world began. Look in your purse or your wallet: Did someone actually invent the idea of replacing real goods and services with a medium of exchange? Are we right to view the abstraction of goods and services that we call money as an invention? We certainly are, but the invention took place in several stages. The first stage dates to the dawn of recorded history. As people from different places bartered and traded their produce, they needed frames of reference to set the value of goods. So they started referring the value of everything to such everyday trade items as cattle or metal. This process was generalized as early as 4,000 B.C. by using the weights of certain metals—usually gold, silver, or copper—as a reference. When the Bible uses the word talent, it is actually referring to a unit of weight. Fifty- or sixty-pound copper talents were a regular medium of exchange around the Mediterranean by the ninth century B.C. The next stage was for governments to certify a particular medium of exchange. The Chinese did so in the eighth century B.C. when they put government inscriptions on certain exchange goods. The lonians began inscribing talents a century later. Lydian Greeks minted the first coins

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just after 650 B.C. A coin takes the abstraction one step further by inscribing a valuable piece of metal with a guarantee that it has value, even though it is separate from actual goods. The phrase "rich as Croesus" refers to the fifth-century B.C. Lydian king Croesus, famous for minting coins. Greek coins soon reached an artistic level that would not be matched until modern times. The next stage of abstraction was to replace valuable metal with paper money. When that happened, money became only symbolic of material goods with no value of its own. The Chinese government issued paper money in the twelfth century, but Europe has only dared to do so during the last three hundred years. Now we have reached yet another stage in the process of abstraction. We call the whole process of barter into computers, and we reduce our balance of cows, autos, and labor to electronic record keeping. Our goods and services are converted into an agreed-upon figure of merit (call it the dollar or the yen) and weighed against one another in electric pulses. We still barter with each other, but the medium of exchange has, at last, become so abstract as to be completely incorporeal. And that cannot be the end of abstraction. We have further to go. Subtler measures of value will emerge. The next medium of exchange will surely give trade value to immaterial information. The old term intellectualproperty, which tries to equate information and property, will give way to something more sensible. But what? It might even become clear in my lifetime; I certainly hope it will in the next generation. Yet the common place of barter, trade, and real goods remains present in our use of money. That's why the physical medium of money reflects our common aspirations with amazing directness. Turn coins about in your mind and you realize that they are the most durable written record of humankind. They reflect our myths and legends. They tell what we honor and what we find beautiful. American coins are much plainer and more static than most, yet even they display buffalo and Indians, wheat, liberty represented by a woman, bald eagles, and former presidents. They affirm our trust in God, variable though that conviction may be. Coinage is an odd technology, since coins are three things at once. They are a historical record, they are often works

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of art, and, of course, they remain a claim to goods and services. Since (until recently) the metal used to make coins had value, that claim can linger long after their issue. Bronze coins minted by the first-century Roman Emperor Domitian were still being used in Spain as late as the seventeenth century. Philip IV finally called them in and had them restamped. The first time I ever held an ancient coin in my hand, its expressiveness took my breath away. It was a late second-century B.C. Roman denarius. Jupiter's picture was on the front and, on the back, was a quadriga, a Roman war chariot. The rim was chipped all the way around, a result of the old way of making coins. After the silver blank had been stamped with the images, fragments were then nipped out of the unstamped rim until the coin had the right weight. That finicky little silver-saving process gave us the word penny-pinching. It also showed that the coin was solid, not just silver-plated. A century later, the new gods, the imperial Caesars, replaced the old household deities on the front of the denarius. The republic was now an empire. (The old war chariot survived for a while; Rome kept its interest in war.)3 I study a handful of contemporary Cayman Island coins and wonder what Caymanians think about. The coins tell me that they voluntarily claim membership in the British Commonwealth. Queen Elizabeth graces all their coins. But on the other side are boats, birds, shrimp, and the Caymanian national symbol, the turtle. Anyone looking at these coins a thousand years from now will be able to see the islands and their natural beauty through Caymanian eyes. Money, after all, represents the work of our hands—our technology. Our interest in money has a component that is a great deal more honorable than mere greed. Money represents what we do. And what we do is what we are. A curious biblical remark says that our heart will be where our treasure is. It sounds cynical at first, but it makes perfect sense when we see money as a kind of condensed representation of ourselves. In the end, it is not surprising that we reveal our hearts in this most peculiar art form. We say who we are and what we value when we coin money. At about the same time that ancient thinkers conceived of the talent as a medium of exchange, artisans in that same eastern Mediterranean world were also beginning to create another new technology of the common place. The first glass products appeared about forty-five hundred years ago.

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The evolution of both technologies has been glacial. Like coins, decorative glass and glass tableware (bowls, goblets, dishes) have been recurring forms of high art since the Hellenistic era. Yet something as wonderfully utilitarian as a uniform windowpane was not generally available until after paper money was. The ancient Egyptians and Greeks made crude glass decorations, but today's basic soda-lime glass—made of sand, limestone, and sodium carbonate—is only about two thousand years old. The first glass of any real quality was made in Hellenistic North Africa around 300 B.C. Soda-lime glass followed quickly on its heels, and both the Hellenistic Greeks and the Romans after them made it into fine tableware. Such tableware remained the most common glass product for a long time. The stained-glass art of the Gothic cathedral was so sophisticated that we might think glass handling had reached a high level of perfection by that point. Actually, the skill that had been perfected, one that seems to be beyond anything we know how to match today, was coloring the glass. A medieval window admitted light, but it was seldom smooth enough to provide a clear view. Cathedral windows were meant to admit light, but they did not even try to display the outside world. What they did do beautifully was to provide illuminated Bible stories for the faithful, who for the most part could not read. Medieval glassblowers made two kinds of flat glass sheets. By one technique, an Typical early-nineteenth-century crown-glass-making operation, from the 1932 Edinburgh Encyclopaedia. artisan would blow a large cylinder, then split the cylinder open and flatten it out while it was still hot. The second flat glass sheet was called crown glass and was made by spinning molten glass and letting centrifugal forces spread it out from a central point. Crown glass was the most common form of flat glass for centuries. It underwent considerable refinement, but even as late as 1800 most domestic windows still displayed the characteristic umbilical imperfection, called a crown, at their centers. The French had developed the superior, but expensive, plate glass process in the latter part of the eighteenth century. First, molten glass is poured out in a mold; then the glass needs expensive grinding and pol-

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ishing. To provide you and me with cheap, high-quality domestic windowpanes, molten glass had to be rolled out in smooth, continuous sheets, and that couldn't be done until we had modern process machinery. It was in the early iSoos that the first inexpensive rolled window glass became available. That was less than two centuries ago. The windowpane again reminds us how much inventive genius is embedded in taken-for-granted technology. It is the result of complex high-temperature chemical and mechanical processes. Yet few things give our daily lives the soul-settling grace of these unobtrusive bridges to the outer world. Like so much really good technology, this one is at its best when it is completely invisible. About the same time medieval artisans were creating Bible textbooks of light and color in the walls of their cathedrals, the use of coal was just becoming commonplace in the European economy. Isolated reports told of coal burning by the ancients, yet Marco Polo had still been surprised by Chinese coal burning in the late thirteenth century. He would also have been surprised if he had traveled to northern Europe and England. By then, the English were using coal for smithing, brewing, dyeing, and smelting. They had even started exporting some to France. By the thirteenth century, millwrights had spent two hundred years consuming the European forests to make their waterwheels and windmills. Wood was becoming too precious to use as a fuel. At first it was replaced by surface coal (often called sea coal because the more obvious outcroppings were found on the coast). By far the largest deposits of sea coal were in England. The reason we do not bring coals to Newcastle is that Newcastle, in particular, was surrounded by huge fields of sea coal. Coal was mined in open cuts, thirty feet deep, so Newcastle was soon girdled by a dangerous maze of water-filled trenches. Sea coal was filthy stuff, loaded with bitumen and sulfur. It created environmental problems from the start. An anonymous fourteenthcentury balladeer vented his anger at its use: Swart smutted smiths, smattered with smoke, Drive me to death with din of their dints,... The crooked caitiffs cryen after col! col! And blowen their bellows that all their brain bursteth.4 But the medieval population explosion drove people to use this foul fossil fuel anyway. For a hundred years medieval environmentalists

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fought with medieval industrialists over its use. Then famine and plague ended their argument until the middle of the fifteenth century. The repopulation of Europe drove people back to coal, but now they were armed with new techniques gained from mining metal. It takes a hot, clean-burning flame to smelt metal. That was once done with charcoal—a fairly pure carbon residue left after the volatile components had been burned off, wood. So when wood shortages reappeared, they were magnified not only by rising populations but by the rising demand for metals as well. As miners followed coal seams down into the earth, mining it the way they had learned to mine metal, they finally reached the much cleaner hard coal we use today. And that deepmined coal also served to replace wood in the smelting process. Coal and metal drove miners deeper into the earth until in the seventeenth-century they were stopped by the water table. With their appetites whetted for fuel and metal, our forebears became desperate to feed their hunger. By now this is all too familiar. Human ingenuity creates new human appetites, which are eventually met by new ingenuity. It is as frightening as it is heartening to see how we find eleventh-hour means for keeping those appetites sated. Of course the deforestation that brought about the need to take up coal was driven by far more than just the construction of water wheels and windmills. Northern Europe had been built upon its early abundance of wood. Much is written about the economics of wood, but we know all too little about the tools that made windmills, Chippendale chairs, or early American desks. The catalog of a Smithsonian Institution collection of hand woodworking tools, published several years ago, helped to remedy that.5 These tools date from the seventeenth century up into the early twentieth century—a period spanning a little more than a century on either side of the Industrial Revolution—and they powerfully mirror their times. Most woodworking tools survived this period without changes to their basic character. Seventeenth-century planes, saws, clamps, and chisels changed in their outward appearance, but it is easy to recognize them for what they are. Only one fundamentally new tool arose in that period, and it's one I never would have thought of: the gimlet auger, of all things—a tool we seldom see today. By the nineteenth century the quality and extent of metalwork in wood-working tools had greatly increased. We find all sorts of fine screw fittings and adjustments that did not exist two hundred years ear-

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lier. Hand tools generally began to reflect a new style. It is almost as though the fine lines of the furniture they were making were rubbing off on them. The sinuous shape of today's axe handle—with the end curving to give the user a better hold—was in place by the nineteenth century. So was the comfortable pistol grip you expect to see on a carpenter's saw. These changes began in the eighteenth century, when people began to see tools as instruments. Perhaps the breath of eighteenth-century science was blowing into the cabinetmaker's shop. During these years, a profusion of stylish new precision measuring instruments arose to support hand tools, such as fancy calipers and dividers. But the tools themselves also began to look like scientific instruments. We see a hundred-year-old drill brace made of heavy brass with clutches, ratchets, and shiny japanned handles. Do you remember the lovely old wood plane, made of brass and tool steel—the array of adjustment knobs, the beautifully formed wooden handles? We still do woodwork. We still seek the essential pleasure of shaping wood with our own hands, but now we use power tools. Tools are intimate possessions. They reflect the way we see ourselves. I may be nostalgic for turn-of-the-century tools and for the lost harmony of wood, brass, steel, and form, but when the chips are down, I am a creature of this world. When I want to make a hole, I reach for a power drill. Consider next a truly elemental technology of the common place. Like wood, textiles are the subject of a great deal of economic history. A nearly invisible item was, for centuries, essential in the use of textiles: the ordinary straight pin. An old nursery rhyme says, "Needles and pins, needles and pins, when a man marries his trouble begins." The lowly dressmaker's pin was once a metaphor for commonplace household necessity. Most people made their clothes at home in the early nineteenth century, and dressmakers absolutely needed pins. But pins were hard to make. They were once made by hand in home production lines, with each person doing one operation. In his poem "Enigma," the eighteenth-century poet William Cowper described a seven-man pinproduction line: One fuses metal o'er the fire; A second draws it into wire; The shears another plies, Who clips in lengths the brazen thread

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For him who, chafing every shred, Gives all an equal size. A fifth prepares, exact and round The knob with which it must be crowned; His follower makes it fast; And with his mallet and his file To shape the point employs awhile The seventh and the last. But pin making was actually more complex than Cowper s sevenstage process suggests. Eighteenth-century economist Adam Smith described eighteen separate steps in the production of a pin. Small wonder, then, that pin making was one of the first industries to which the early-nineteenth-century idea of mass production was directed. The first three patents for automatic pin-making machines were filed in 1814,1824, and 1832. The last of these, and the first really successful one, was granted to an American physician named John Howe. Howe's machine was fully operational by 1841, and it has justly been called a marvel of mechanical ingenuity. It took in wire, moved it through many different processes, and spit out pins. It was a completely automated machine driven by a dazzlingly complex array of gears and cams. When Howe went into production, the most vexing part of his operation was not making pins but packaging them. You may have heard the old song that goes: "I'll buy you a paper of pins,and that's the way our love begins." Finished pins had to be pushed through ridges in paper holders, so that both the heads and points would be visible to buyers. It took Howe a long time to mechanize this part of his operation. Until he did, the pins were sent out to pin packers, who operated a slow-moving cottage industry, quite beyond Howe's control.6 So we glory in the grander inventions—in steam engines and spaceships, gene splicing and fiber optics. The pin is one more technology that serves us by easing the nagging commonplace needs that complicate our lives. If the TV and the door handles both disappeared from your house, which would you replace first? Making the lowly dressmaker's pin easily available was a substantial blessing to nineteenthcentury life and well-being. We also lose track of the commonplace dimension when we talk about the technologies of getting from place to place. After we've dealt

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with steamboats, automobiles, and airplanes, we discover that we've overlooked the transportation medium that has touched every one of our lives. We mentioned the bicycle at the outset, as it represents commonality of thinking. Now let us look at as it represents commonality in transportation. The history of the bicycle is curiously tied to that of the horseless carriage. Together they represent ways that the poor and the wealthy achieved freedom of movement. The early nineteenth century saw all kinds of new steam-powered vehicles. At first steam carriages competed with locomotives, but the railways won the battle because they made transportation inexpensive in a way steam carriages could not. Trains were confining, and people wanted freedom to travel the roads as they pleased. The new dream of rapid movement had to be individualized. If the answer was not the steam carriage, then maybe it could be the bicycle. Between 1816 and 1818 Scottish, German, and French makers came out with primitive bicycles. They all seated a rider between a front and a back wheel with his feet touching the ground so he could propel himself with a walking motion. This form of bicycle was not new. Such bikes are found in Renaissance stained glass, Pompeian frescoes—even in Egyptian and Babylonian bas-reliefs. But around 1839 the Scottish maker Macmillan added a feature to his "hobbyhorse," as he called it. He added a pedal-operated crank to drive the back wheel—like the pedal-operated chain drive on your bike. Oddly enough, the idea didn't catch on. Not until 1866 did pedals appear on thefronf wheel, like on the tricycles we rode as children. Bicycle use took off after the invention of the front-wheel pedal. But it also led to larger and larger front wheels. The bigger the wheel, the further the bike would move on each turn of the pedal. That led to the dangerously unstable bicycle depicted in so many Currier and Ives prints—the one with the huge front wheel and the tiny back one. In its developed form it was called the ordinary bicycle, but it was nicknamed the penny-farthing because its wheels looked like large and small coins. The ordinary was so tricky it finally gave way to the so-called safety bicycle—the modern bike with two equal wheels, the back one driven by a chain and sprocket. The safety bike resembled MacMillan's hobbyhorse design forty-six years earlier. It went into production around 1885. It soon replaced the ordinary and has been the basic bike design ever since. So the modern bike entered the twentieth century along with the new gasoline automobiles. It freed those people who could not afford

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cars. Now they too could go where they pleased. And oh, the sense of freedom we felt as children when we got our first bikes! They let us fly like the wind and go where we wanted. They were wonderful things. The transition to the new safety bicycle is dramatically illustrated in this heading for an article in the September 1896 Century Magazine. The technologies of the common place remain invisible only until we are separated from them. The literature of exploration and settlement reveals all the ingenious means people find for re-creating the most basic of our technologies. Ellen Murry, then at the Star of the Republic Museum at Washington-on-the-Brazos, Texas, has written about the early technologies of this rough land. The Republic of Texas seceded from Mexico and became a separate nation in 1836. It was a wild, unsettled nation. Early Texans were intimate with untimely death. Mourning and memorializing death were basic social activities. A disturbing level of attention was paid to the crafts of preparing, displaying, transporting, and burying the dead. With death so commonplace, women sustained life by marrying in their mid- to latter teens and by raising lots of children. Normally, six or seven kids survived after murderous infant mortality took its toll. Texas frontier women—often managing despite their husbands' long absences—did the child rearing, educating, and civilizing. These settlers had little access to any developed medical technology. They fought illness by trying to rid the body of whatever ailed it. They embraced the medieval idea of curing by bloodletting, emetics, and laxatives. "Puke and purge" was a saying that began and ended most medical treatment on the Texas frontier. People did recognize that unsifted whole-wheat flour was good for the digestion. A major apostle of that notion was Sylvester Graham— promoter of the Graham cracker. He also suggested that it reduced alcoholism and damped the bothersome sex drive. Bathing, too, was a form of medical treatment. It had little other place in everyday life. In 1840 a writer denounced the bathtub as "an epicurean innovation from England, designed to corrupt the democratic simplicity of the Republic." Early Texans washed their hands and faces before meals, but it was normal to go a year or more between baths.

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Tobacco, especially chewing tobacco, was an early Texas fixation. Children were taught to use the stuff. Cuspidors were universal furnishings. A visitor to the Texas Congress said, "The way the members were chewing Tobacco and squirting was a sin to see." And an Austin church posted this notice: Ye chewers of the noxious weed Which grows in earth's most cursed sod, Be pleased to clean your filthy mouths Outside the House of God. The Republic of Texas lasted less than a decade. Any way you hold them up to the light, the people who formed it were tough, independent, adaptive, and idiosyncratic. We get to know them when we look at their daily means—the rough-hewn technologies by which they carved freedom and the good life out of a harsh, and seemingly infinite, land.7 And finally, a brief look at one of the most common technologies of them all, the technology of waste disposal. Every time I teach the history of technology some student tells me, often with a salacious grin, that the flush toilet was invented by a nineteenth-century Englishman named Thomas Crapper. Well, he did not really invent the flush toilet, but his name does indeed hover over its history. The modern flush toilet consists of three essential components: a valve in the bottom of the water closet, a wash-down system, and a feedback controller to meter the next supply of wash-down water. The first two were incorporated in the toilet developed by a courtier of Queen Elizabeth, a poet named John Harington. The third element, the float-valve feedback refill device, was added in the mid-eighteenth century. The flush toilet was, in fact, an important landmark in the Industrial Revolution. It was closely tied to the new technology of steam-power generation, since the important concept of automatic control of liquid levels arose both in steam boilers and in the tanks of these new water closets. Thomas Crapper was a real person. He was born in Yorkshire, England, in 1837, long after the first flush toilets came into use. His wonderfully tongue-in-cheek biography is told by Wallace Reyburn in a book entitled Flushed with Pride. Thomas Crapper apprenticed as a plumber when he was still a child. By the time he was thirty he had set up his own business in London. He developed and manufactured sanitary

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facilities of all sorts until his death in 1910. He held many patents and was, in fact, an important and inventive figure in the creation of modern water closet systems. But did he really give his name to these systems? Reyburn claims that many American soldiers in World War I were off the farm. They had never seen anything like the classy English water closets and called them by their brand name, much as the English call a vacuum cleaner by the brand name Hoover. The problem with this explanation is that the word almost certainly derives from the thirteenth-century Anglo-Saxon word, crappe. It means "chaff" or any other waste material. The modern form of the word was certainly in use during Thomas Crapper's life. So he was not the inventor of the flush toilet, and it is unlikely that he really gave it his name. What he did do was to carry the technology forward.8 The Thomas Crapper story points out something historians have to guard against. Now and then a really good story comes along—one so well contrived that it should be true, even if it is not. Who wants to admit that no apple ever fell on Isaac Newton's head or that George Washington did not really chop down the cherry tree? What humorless pedant wants to insist that Thomas Crapper did not really invent the flush toilet? Since waste removal is a universal common denominator, anthropologists have used it to answer a question any historian inevitably asks: What was the texture of life in a given period? What was it like to live in ancient Rome, in a medieval castle, or, in this case, in an early Texas mansion? Life was primitive inland, but Galveston was another matter. Galveston was Texas's major port and a town marked by some grace and elegance. Yet we gain one of our best views of the lives of Galveston's wealthy by diving into a old privy. Ashton Villa is a mansion that survived the terrible 1900 Galveston hurricane. The house was built by James Brown, a wealthy businessman who kept slaves before the Civil War. It is very well made because he used the work of slave craftsmen instead of manufactured materiel. Urban archaeologists Texas Anderson and Roger Moore have shown how to wring the mansion's story from it. The old privy, long since covered over and forgotten, becomes their window into the past. More than an outhouse, it was also a general trash dump. A huge hole in the ground, no longer septic, it contains layers of trash that reveal the quality of life from the late 18505 up through the late Victorian period. Galveston rode out the Civil War better than most of the South, and

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so did Brown. After the war he furnished the house with fine European porcelain. His family ate inchthick T-bone and porterhouse steaks; they disdained chicken and pork. They drank elegant wines and cognacs, but not hard liquor. The ladies imported French perfume and expensive facial astringents. Brown's business involved selling new technology to the American West. His mansion displayed all the latest stuff—the first flush toilets in Galveston, and the first electric lights only a few years after Edison introduced them. Sifting through century-old detritus, we begin to sense the finery and feel of the place and to know the Items found in the Ashton Villa privy pit included fine china, perfume, wine and actual people. We begin to understand the combined medicine bottles, and bones from the best tyranny and vision that Brown represented. To say cuts of meat. (Photos courtesy of Texas merely that he exploited slaves or that he brought Anderson) technology to the West is like trying to know baseball from sports-page statistics. But the intimacy of an accurate look into the drawing room or the servants' quarters is an understanding of a whole different order when we have the wits to look at them through a trash heap. So history is revealed where history is made. When we look for history we ultimately find it by looking in the commonest of common places. Kings and emperors only appear to shape our world. Technology, culture, and the ghosts of history itself are born at our human center. To know them, we must know the common place.

If we had a keen vision of all that is ordinary in human life, it would be like hearing the grass grow or the squirrel's heart beat, and we should die of that roar which is the other side of silence. —George Eliot, Middlemarch, Chapter XX, 1871

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Science Marries into the Family

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he old Latin word scientia was not much used to designate ordered knowledge until recent times. Galileo would not have called himself a scientist, nor would Newton or Leibniz. Even two hundred years ago Lavoisier still called himself a natural philosopher. Yet each of those people contributed to the radical change that turned natural philosophers into today's scientists. The change was complex. Roughly speaking, it could be called the evolution of the scientific method. It began during the 14805, when the new printed books first included accurate illustrations of an observed world. Until then, first Christians and then Moslems had adhered to the Platonist idea that truth is to be reached by deduction far more than by observation. Throughout the sixteenth century the new observational sciences of botany, anatomy, descriptive geometry, geography, and ethnography all took form. In a series of bold steps the new media of print and illustration wrenched a world still shaped around Platonist thinking. Then, in the early sixteen hundreds, Galileo Galilei and Francis Bacon in particular codified the changes that had been afoot. Galileo did more than anyone to establish the methods of the new science, and Francis Bacon framed its philosophical stance. In 1620 Bacon wrote down the new view of nature in unmistakable terms in his Novum Organum. He directly contradicted the Platonists' belief that truth is to be found in the human mind when he said, "That which nature may produce or bear should be discovered, not imagined or invented." For over a century, a new breed of scientists had been

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learning how to take better account of empirical fact than medieval scientists had done. Now Bacon told us flatly that this was the only proper way to practice science. After 1600 Europe gained two new tools of inquiry, both of which led away from medieval thinking. The shift to observational science was certainly strengthened by new kinds of measuring instruments. Clock making was a technology that had led to a new precision in mechanisms. The seventeenth century gave us the telescope, the thermometer, the vacuum pump, and the microscope. But a second major force was also afoot, and its relation to the shift in scientific method was more complex. New forms of practical mathematics offered lay people means to perform calculations. Mathematics is an inherently Platonist endeavor. It is done within the human mind, with minimal recourse to the outside world. At the same time it is also the ultimate means for speaking absolutely objectively. Mathematical outcomes admit very little meddling by our subjective whims. Armed with new mathematics and new instruments in the laboratory, science was not only in a better position to deal with external realities. It was also in a position to take part in the work of technology (which is, after all, the means for manipulating external realities). Natural philosophers of an earlier age had seen no relation between their work and the business of making things. Now a wedding would unite the activity of describing the world and that of shaping the human environment. One of the early progeny of this marriage was architecture. Medieval masons had taken stonecutting very far from the one-dimensional stack of rock that made a Greek column, or the two-dimensional shape of a Roman arch. They had learned to shape masonry into complex rib work on the roofs of vaults, into helical stairways, and into arches that intersected at strange angles. Yet they had done this work without using formal geometry. Geometry had been central to medieval scholasticism, but it had been an exercise in logic, not a means for making things. Masonry was crying out for geometric assistance, but the inevitable joining of mathematics to masonry did not come about until the end of the fifteenth century. When it did, a new baroque architecture emerged—one based on exact geometrical methods. Then architects started using precise intellectual apparatus to design magically spatial forms: barrel vaults, biased arches, helicoids, and embellished versions of the medieval trum-

7'

pet squinch. A trumpet squinch is a conical arch that emerges smoothly where two walls meet in a corner. It is a beautiful complicated support for the floor above. Just imagine trying to cut the stone blocks that can be piled into such a form!1 The wedding of modern, math-driven, observational science to fluid baroque architectural forms was only one of many such marriages. Those unions bore remarkable fruit, but make no mistake: They were weddings of opposites, reminiscent of the gladiatorial combat between a competitor using a net-and-trident and one carrying a shield and short sword—a perfect balance of evenly matched, but quite different, adversaries. The partners retained their own identity, and they sustained a ! level of running combat. A trumpet squinch, as pictured Throughout the last four centuries, science and tech\ntteDictionnaireRaisonnede nology have provided the essential tension needed to /'Architecture, 1868. j • „.!_ • j T» j > J- *. r 1.1 drive the mind, lodays propagandists tor schools andJ industries like to celebrate the cooperation of these two oddly matched contestants. But what science and technology have achieved has sprung from something far more deep-seated than mere cooperation. Our complex modern world was created by these slightly irritable old companions who know, but do not like to admit, that they can no longer live without each other. Galileo, who lived from 1564 to 1642, embodied all these contradictions. When he was young, his English contemporary Robert Burton used these words to describe Aristotle's idea of how objects fall (versification is mine): There is a natural place for everything to seek, as: Heavy things go downward Fire upward, And rivers to the sea.2 It was in the nature of falling, Aristotle had insisted, that heavy objects seek their natural place faster than light ones—that heavy objects fall faster. Galileo took an interest in rates of fall when he was about twenty-six years old and teaching mathematics at the University of Pisa. It seemed to him that if Aristotle was right, a body unimpeded by air resistance

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should fall at a speed proportional to its density. He decided to test his elaborated Aristotelian theory with an experiment. But there was no tradition of either making or describing controlled scientific experiments in Galileo's day. So Galileo's description of his experiments was quite skimpy by today's standards. Indeed, he doesn't actually claim to have done the experiment at all. Throughout his dialogs in Two New Sciences he peppers the pages with statements that hover between the language of deduction and that of observation. Surely a gold ball at the end of a fall through a hundred braccia will not have outrun one copper by four inches. This seen, I say, I came to the opinion that if one were to remove entirely the resistance of the medium [in this case, the air] all materials would descend with equal speed.3 Reading his dialogs, you never quite know if you are reading about Aristotelian observations or Platonist thought experiments. He seems to have dropped two balls, one of oak and one of lead, from a tower. But what sizes and what tower? If it was a real experiment from a real tower, we can be pretty sure it was the Leaning Tower of Pisa. Since Galileo spoke the language of Platonist discourse, he left historians of science wondering whether he actually did the experiment. Maybe he just reported what should have, happened. Certainly that is how the Platonist philosophers around him studied nature. One result of the experiment surprised Galileo and one surprises us. Galileo found that the heavy ball hit the ground first, but by only a little bit. Except for a small difference, which he correctly attributed to air resistance, both balls reached the same speed. That surprised him; it forced him to abandon Aristotelian writings about motion. If he really did the experiment, it was a turning point in the practice of science. But what surprises us is what Galileo said happened just after he released the two balls. The lighter ball, he said, started out a little bit faster than the heavy ball. Then the heavy ball caught up. That sounds crazy in the light of known physics. So physicists Thomas Settle and Donald Miklich reran the experiment in front of a slow-motion movie camera. An assistant held two four-inch-diameter iron and wooden balls at arm's length, as Galileo would have held them to clear the wide balustrade at the top of the Pisa tower. A close study of the film proved that when someone tries to drop both balls at once, their strained mus-

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cles fool them. They consistently let go of the lighter one first. So what Galileo accurately reported is what really would have happened, and we are left with no doubt that he actually did the experiment.4 Galileo's tower experiment turns out to have been no fable after all. It was a very early controlled scientific experiment—the means Galileo used to become the first real challenger of Aristotle. The meaning of "Aristotelian science" can become confusing because Platonist medieval science had been built upon the body of knowledge that Aristotle had provided, much of it correct and some of it in error. But Medieval science then lost sight of the observational methods that Aristotle had created to gain his knowledge. The irony is that Galileo used

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